The "Sustainable" Plastic Dilemma: An Exploration of the Environmental Impacts and Social Perceptions of Bioplastics

Item

Title
Eng The "Sustainable" Plastic Dilemma: An Exploration of the Environmental Impacts and Social Perceptions of Bioplastics
Date
2018
Creator
Eng Pierce, Lucy S
Subject
Eng Environmental Studies
extracted text
THE “SUSTAINABLE” PLASTIC DILEMMA: AN EXPLORATION OF THE
ENVIRONMENTAL IMPACTS AND SOCIAL PERCEPTIONS OF BIOPLASTICS

by
Lucy S. Pierce

A Thesis
Submitted in partial fulfillment
of the requirements for the degree
Master of Environmental Studies
The Evergreen State College
June 2018

©2018 by Lucy S. Pierce. All rights reserved.

This Thesis for the Master of Environmental Studies Degree
by
Lucy S. Pierce

has been approved for
The Evergreen State College
by

________________________
Shawn Hazboun, Ph.D.
Member of the Faculty

________________________
Date

ABSTRACT
The “Sustainable” Plastic Dilemma: An Exploration of the Environmental Impacts and
Social Perceptions of Bioplastics

Lucy S. Pierce

Bioplastics, plastics derived from renewable feedstocks, have grown in popularity since
the 1980s. The bioplastics market is largely comprised of packaging for the food and
beverage industry. The labeling of bioplastics primarily relies upon a standardization and
certification system influenced by industry groups and loosely upon government and
academic knowledge. Labels such as bio-based, biodegradable, and compostable convey
a variety of meanings to purchasers, distributors, and consumers. A lack of understanding
about these products is prevalent. Therefore, this study attempted to address attitudes,
knowledge, and the use of bioplastics within local food service businesses in Olympia,
Washington through a quantitative survey and qualitative interviews. Additionally, the
environmental impacts of bioplastics were examined through a review of the standards,
certifications, and Life Cycle Assessments. The survey results demonstrated significant
use of bioplastics, with almost half of businesses in downtown Olympia using them.
However, the qualitative interviews revealed a lack of knowledge about the standards and
certifications. Respondents felt uncertain about whether or not bioplastic’s environmental
impacts are less harmful than traditional ones. To inform the bioplastic industry and
regulatory policies, this thesis recommends more research on best practices for end-oflife disposal in real life, how and where bioplastics are currently utilized, and
environmental assessments that not only employ quantitative data, but merge both
quantitative and qualitative methods.

Table of Contents

List of Figures ...............................................................................................................vi
List of Tables .............................................................................................................. vii
Acknowledgements .................................................................................................... viii
Introduction ................................................................................................................... 1
Chapter 1: Overview of Bioplastic Standards and Certifications ............................... 6
Bio-Based ....................................................................................................................9
USDA BioPreferred ................................................................................................... 11
Biodegradable ............................................................................................................ 12
Compostable .............................................................................................................. 16
International Organization for Standardization (ISO) ................................................. 17
American Society for Testing Materials (ASTM) ....................................................... 18
European Norm 13432 ............................................................................................... 20
Federal Trade Commission Green Guide (FTC) ......................................................... 23
Certifications ............................................................................................................. 25
European Certifications .............................................................................................. 26
United States Certifications ........................................................................................ 27
Chapter 2: Literature Review ..................................................................................... 28
Ecological Modernization Theory (EMT) ................................................................... 28
Consumer Awareness and Perceptions of Bioplastics ................................................. 32
Life Cycle Assessment (LCA) .................................................................................... 36
Environmental Impacts of Bioplastics Determined from Life Cycle Assessment ........ 40
Chapter 3: Methods ..................................................................................................... 42
Research Objectives ................................................................................................... 42
Site Description ......................................................................................................... 43
Sampling and Data Collection Methods...................................................................... 44
Survey ....................................................................................................................... 44
Interviews .................................................................................................................. 47
Chapter 4: Results and Discussion .............................................................................. 52
Results: Survey ............................................................................................................ 52
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Survey Results: Composting ...................................................................................... 53
Survey Results: Table Service and Counter Service .................................................... 55
Survey Results: Bioplastic Product Form ................................................................... 57
Survey Results: Bioplastic Brand ............................................................................... 58
Survey Results: Number of Employees ...................................................................... 59
Conclusion: Survey Results ........................................................................................ 60
Results: Qualitative Interviews ................................................................................... 61
Social Category.......................................................................................................... 62
Technology Category ................................................................................................. 73
Environmental Category ............................................................................................ 76
Discussion..................................................................................................................... 81
Chapter 5: Conclusion and Recommendations .......................................................... 85
References .................................................................................................................... 88
Appendices ................................................................................................................... 94

v

List of Figures
Figure 1.1: USDA BioPreferred Logo ……………………………………………. 12
Figure 1.2: European Certification Logos ……………………………………….... 26
Figure 1.3: United States Certification Logo ……………………………..……..… 27
Figure 3.1: Sampling Boundaries …………………………………………….…… 46
Figure 4.1: Bioplastic Use by Type of Business …………………………………...56
Figure 4.2: Most Common Forms of Bioplastics ……………………………….... 58
Figure 4.3: Most Common Reported Bioplastic Brands …………………….….…59

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List of Tables
Table 1.1: Bioplastics Variations ………………………………………….......….…. 9
Table 1.2: Bio-based Definitions in the United States……………………….…....… 10
Table 1.3: National and International Standards for Biodegradable Plastics .….….....15
Table 1.4: ISO Standards Related to Composting ………………………….….……..18
Table 1.5: ASTM Standards Related to Composting …………………………..…….19
Table 1.6: Compostable Plastic Standards: A Comparison ……………………..…... 22
Table 2.1: ISO LCA Steps ……………………………………………………….…. 38
Table 3.1: Codes by Generalized Category ……………………………………….... 50
Table 4.1: Bioplastics Use by Business Type……………………………….………. 53
Table 4.2: Composting Practices of Businesses …………………………….………. 53
Table 4.3: Use of Compost with Bioplastics ………………………………….…….. 55
Table 4.4 Bioplastic Use by Number of Items Used ………………………….…….. 57
Table 4.5 Number of Employees and Bioplastic Use of Businesses ………….…….. 60

vii

Acknowledgements

First, thank you to all the survey and interview participants in downtown Olympia for
their time and insights. Thank you to my thesis advisor Shawn Hazboun for her
unwavering support and understanding throughout the thesis process. Thank you for the
continuous encouragement, suggestions, and inspiration. Thank you to Scott Morgan for
his mentorship, wisecracks, and wisdom. I am grateful for the support and assistance
from all MES faculty and staff. Lastly, a special thanks to my family and friends for
giving me the strength and motivation to accomplish any task I set my mind to.

viii

Introduction
Bioplastics have become popular alongside the increasing awareness of traditional
petroleum-based plastic pollution. Historically, plastic was seen as terrestrial litter on city
sidewalks and sides of interstates, but now it is polluting our waterways, oceans, and marine life,
encompassing all ecosystems. Today, public awareness of the harms of plastics is widespread.
Plastic pollution is ubiquitous due to the resiliency and permanence of petroleum-based plastic
materials. Plastic has the potential to exist for hundreds, even thousands of years (Wang, Tan,
Peng, Qiu, & Li, 2016). The origin of modern polymers, commonly known as plastics, can be
traced back to the Second World War. War time spurred research and development of alternative
materials to wool, steel, and glass (Mulder, 1998). After World War II the commercial
applications of plastic were explored for consumer products and packaging, causing global
production of plastics to skyrocket from around one million tons in 1950 to thirty million tons in
1970 (Schouten & Van der Vegt, 1991). As described by Mulder (1998), the world is living in a
Plastic Age. Prior ages like the Stone Age, Bronze Age, and Iron Age are distinct stages in
history characterized by materials and modernity (Mulder, 1998). The global use of plastics has
transformed daily life for billions of people, but with the proliferation of plastics has come severe
environmental impacts. Today, many believe petroleum-based plastics are a burden for the
environment and their invention unintentionally created further problems (Talon, 2014). Plastic
pollution is a global problem; plastic bags and microplastics, plastics under 5 millimeters, are the
most prevalent polluters around the world due to their size, thickness, and quantity (Xanthos &
Walker, 2017). Physical pollution from plastics is only one factor in the plethora of
environmental issues with them, but unlike petroleum-based plastics, the majority of bioplastics
are designed to be less permanent. Petroleum-based plastics cause terrestrial and aquatic
pollution, exhaust landfill space, emit toxic and greenhouse gas emissions, and are difficult to
1

fully recover through reuse and recycling (Álvarez-Chávez, Edwards, Moure-Eraso, & Geiser,
2012; Ren, 2003).
Bioplastics, a recent innovation, are broadly defined as plastics derived from biomass
and renewable sources. They are used as an alternative material to petroleum-based plastics
primarily in the form of consumer goods and packaging (Kinsha, Niesten, Negro, & Hekkert,
2016). Bioplastics are marketed as a solution to the environmental impacts of traditional,
petroleum-based plastics because they are manufactured from renewable sources and have the
possibility of breaking down in the environment (Mosko, 2012). However, bioplastics’ ability to
reduce environmental impacts is highly debated.
The bioplastics industry is “green” both in its intentions to create more sustainable
plastics, and its burgeoning status on the global market. Bioplastics are a fairly recent innovation,
first appearing commercially in the late 1980’s in Europe and the United States (Darby, 2012).
Although they are a new addition to the plastics industry and only share about two percent of the
global plastics market as of 2015, the projected growth of bioplastics is astonishingly high. The
association group, European Bioplastics, predicts a twenty percent increase in the global
bioplastic market by 2020, setting the total global market value at 30.8 billion dollars (Bhilare,
2018). The largest sector of bioplastics use is packaging, comprising sixty percent of the total
bioplastic market in 2017 (Global Market for Bioplastics to Grow by 20%, 2017). Other sectors
where bioplastics are commonly found are in the textile, automotive, consumer goods, and
agricultural industries. This study focuses on bioplastic packaging, specifically packaging in
food service.

2

In a nationwide poll of 1,107 people in the United Sates by SPI: The Plastic Industry
Trade Association, twenty-seven percent of the participants said they were somewhat familiar
with bioplastics. However, thirty-four percent of participants said they were completely
unfamiliar with bioplastics. In addition to an unfamiliarity with bioplastics, eighty-six percent of
participants said they had never seen or were unsure if they had seen the U.S. Department of
Agriculture Certified Biobased Product logo (Mashek, 2016). These statistics demonstrate the
public’s low level of knowledge about bioplastics. This lack of knowledge is only one element in
the complex bioplastic industry. In a recent report from SPI: The Plastics Industry Trade
Association, they highlight some of the other challenges within the bioplastic industry: confusion
with terminology, lack of industry cohesiveness, lack of infrastructure for end-of-life disposal
other than landfill, limited legislation and regulation, lack of international harmonization of test
standards and certification, and limited availability of non-food renewable feed stocks like
sawdust, hemp, and byproducts like husks or peels (Mashek, 2016).
In addition to these challenges within the industry, the environmental benefits of
bioplastics have not been fully determined. While many believe bioplastics are less harmful than
traditional plastics, the negative environmental effects of bioplastics include a wide range of
problems. In order to manufacture bioplastics, renewable raw materials are needed. Industrial
agriculture practices are typically utilized for the renewable raw materials. These industrial
processes have many negative environmental effects including high fossil fuel energy
requirements, human and wildlife exposure to pesticides, significant water use, competition with
the global food supply, changes in land use, deforestation, loss of biodiversity, and
eutrophication, a process where excess nutrients from fertilizers enter waterways and cause the
overproduction of plant matter, resulting in the depletion of oxygen (Álvarez-Chávez et al.,
3

2012). On the production side, it is unclear if the levels of greenhouse gas emissions during
bioplastics manufacturing are actually lower than traditional plastics. Finally, for end-of-life
environmental problems most are related to a lack of industrial composting infrastructure (Yates
and Barlow, 2013).
To address the complexities and problems within the bioplastic industry more research is
needed. To add to the literature, this research asks the following questions: 1) Are bioplastics
less environmentally harmful than their petroleum-based counterparts? 2) How are bioplastics
being perceived and used within the food service industry, their most common application? The
goal of this research is to approach these questions holistically, rather than focusing solely on
quantifiable environmental impacts, like pounds of greenhouse gas emissions. Three
methodological approaches were used, including a review of relevant standards and regulatory
measures, quantitative surveying of food service businesses, and qualitative interviews of food
service managers.
The theoretical framework used for this study, Ecological Modernization Theory (EMT),
provides a contemporary interpretation of macro-level societal- environmental interactions. EMT
has evolved over the past 30 years, but at its earliest stages in the 1980’s it developed as a new
way for thinking about environmental reform, or how society avoids environmental crisis. One
of the founders of the theory, Huber (1985), emphasized economic growth and the market as
means for environmental reform, where technology and science could provide enough
modernization to drive society from environmental crisis, rather than state actors leading the
environmental movement.

4

Fundamentally, EMT “analyzes how contemporary industrialized societies deal with
environmental crisis” (Mol & Sonnenfeld, 2000, p. 5). There are five core foundations to
Ecological Modernization Theory: 1) science and technology may have caused environmental
problems, but conversely they can be used for overcoming and avoiding future environmental
crisis; 2) producers, consumers, corporations, and all other market actors have a role in
environmental reforms, not just state agents and governments; 3) less command-and-control
regulation from state agencies and more collaboration with non-state actors on regulatory issues
lead to more environmental reform; 4) social movements have power in environmental decisionmaking institutions, whether public or private; and 5) for modern society to continue we must not
accept a separation between ecology and economics, overlooking the environment is no longer
an option (Mol & Sonnenfeld, 2000). Bioplastics are an appropriate example for EMT because of
their similar time of emergence in society, along with their development as an alternative to
petroleum-based plastics. Characteristically, bioplastics are environmentally reformed plastics
and developed from an advancement in technology and science. However, EMT is only one
theoretical framework for analyzing the bioplastic industry and gaps are identified later in the
study. Nevertheless, this study aims to demonstrate EMT as an applicable way of thinking about
the role bioplastics have played and will continue to play in modern environmental reform.

5

Chapter 1: Overview of Bioplastic Standards and Certifications
This chapter will provide insights into the intricate bioplastic industry regulations. The
most common standardizations used to harmonize the bioplastic industry are described in some
detail, followed by a demonstration of the similarities and differences between the definitions
and testing methods of these standards. In doing so, this study will explain the terms bio-based,
biodegradable, compostable, and why this study applies the umbrella term bioplastic. Following
the descriptions and standards section, the certifications used globally to label and identify
bioplastics will be reviewed. This chapter intends to provide a foundation for understanding the
intricate industry regulations within the bioplastic market. This study will use the following
abbreviations: ISO: International Organization for Standardization, ASTM: American Society for
Testing Materials, CEN: European Committee for Standardization, DIN: Deutsches Institute für
Normung (German institute for standardizations), DIS: Draft International Standard (Associated
with ISO), EC: European Commission (the governing body of the European Union responsible
for legislation and regulations), and EN: European Norm.
In the 1980’s, bioplastics originally manufactured for applications in agriculture, but over
time bioplastics became commercially available to more industries like packaging and consumer
goods where they are more commonly seen today (Darby, 2012). Bioplastics are unlike fossil
fuel-based polymers, as they are produced using renewable resources (van der Zee, 2005). The
decreasing supply of fossil fuels, increasing number of landfills reaching capacity, and the rise of
mitigation efforts for greenhouse gas emissions, drove polymer manufacturers to research
alternative sources for polymer production (Hermann, Debeer, Wilde, Blok, & Patel, 2011;
Kabasci, 2014). In order to replace fossil fuel sources for polymers, a renewable source needed
to be identified. This came in the form of bio-based raw materials like starch, lignin, cellulose,
6

and proteins. These bio-based raw materials are commonly known as agricultural products like
corn, soy, sugarcane, and forestry material or biomass (Alvarez-Chavez et al., 2012; Department
of Ecology State of WA [USDEWA], 2014; Kabasci, 2014). Polymers derived from agricultural
products have inherent properties of biodegradation. Unlike fossil fuel-based polymers, which
have no biodegradable properties, polymers derived from bio-based raw materials are designed
to be less persistent in the environment and decompose through interactions with living
organisms (Lörcks, 1998; Rudnick, 2008). This study uses the term bioplastics because of one
key problem in the industry of manufacturing polymers from renewable sources. The problem is
eloquently stated by Hottle, Bilec, & Landis (2013),
“Biopolymers come in many different forms; they can be derived from renewable
resources and may not be defined within the traditional plastics classification numbering
system 1-6 like polylactic acid (PLA) or they can be partially made from renewables and
synthesized like traditional plastics in the case of bio-based PET” [Polyethylene
Terephthalate] (p. 1899).
The key phrase in this statement is “partially made from renewables”. A biopolymer or
bioplastic falls under the category of either fully derived from renewable raw materials, or it can
also contain petroleum or fossil fuel sources in addition to renewable raw materials (USDEWA,
2014). This study uses the general term bioplastic because bio-based, biodegradable, and
compostable inherently have a variety of different meanings and are made from several raw
materials or fossil fuels. Talon (2014) makes a similar argument and says,
“In the interests of clarity, it should be noted that the term “bioplastic” is to be
understood here in terms of nature, rather than properties. Thus, for our own purposes a
bioplastic is a plastic material created, at least partially, from or with renewable resources
exclusively” (p. 92).

In order to be general, like Hottle et al. (2013) and Talon (2014), this study will use the
term bioplastic. This is appropriate within the scope of this study because the data collection
7

involved interactions with average citizens who typically use the term plastic rather than
polymer. In addition to Hottle et al. (2013), Kabasci (2014), and Talon (2014), others like
Peelman, Ragaert, Muelenaer, Adons, Peeters, Cardon, Van Impe, and Devlieghere (2013),
provide examples of bio-based and fossil fuel-based plastics. Peelman et al. (2013) specifically
studied bioplastics in food packaging applications, which is relevant to this study. Table 1.1
describes the most common bioplastics by their technical name and abbreviation, in addition to if
they are bio-based or petroleum-based.

8

Table 1.1: Bioplastics Variations
Material

Abbreviation

Source

Polyhydroxyalkanoates

PHA

Bio-based

Poly Lactic Acid

PLA

Bio-based

Thermoplastic Starch

TPS

Bio-based

BURS

Bio-based

-

Bio-based

Bio-PE

Bio-based

Bio- PET

Bio-based

Bio-PA

Bio-based

PET

Petroleum-based

Polyethylene

PE

Petroleum-based

Polyamide

PA

Petroleum-based

Polybutylene succinate

PBS

Petroleum-based

Poly trimethylene-terephtalate

PTT

Petroleum-based

Polycaprolactone

PCL

Petroleum-based

Polyethylene succinate

PES

Petroleum-based

Bio-urethanes
Cellulose and Lignin
Bio-polyethylene
Bio-poly(ethylene-terephthalate)
Bio-polyamide
Polyethylene terephtalate

Polybutyrate adipate
terephtalate

PBAT

Petroleum-based

Table adapted from Álvarez-Chávez et al., (2012); Emadian et al. (2017); Hermann et al.,
(2011).
Bio-Based
Bio-based is a term used to describe bioplastics that holds little meaning in terms of endof-life process and mostly refers to the origins of the product. Table 1.2 demonstrates the
variability found in the bio-based definition within numerous organizations, including a
government agency, an international standardization organization, and a business/ NGO working
group.
9

Table 1.2: Bio-based Definitions in the United States
Business-NGO Working
Group for Safer
Chemicals and
Sustainable Materials
(BizNGO)
United States
Department of
Agriculture
(USDA)
American Society for
Testing Materials
(ASTM)

Plastics in which 100% of the carbon is derived from renewable
agricultural and forestry resources such as corn starch, soybean protein,
and cellulose.
Commercial or industrial goods (other than food or feed) composed in
whole or in significant part of biological products, forestry material, or
renewable domestic agricultural materials, including plant, animal, or
marine materials
An organic material in which carbon is derived from a renewable resource
via biological processes

Adapted from Álvarez-Chávez et al. (2012). This table describes 3 different organizations and
their definitions of bio-based plastics.

The U.S. Department of Ecology State of WA (2014) states a bio-based plastic is simply
made from renewable raw materials rather than petroleum, but it does not need to be fully biobased. They distinguish a bio-based plastic might not be biodegradable, or compostable either.
Alternatively, Kabasci (2014) notes a definition of bio-based plastic that is simply “plastics
derived from biomass” (p. 2). This definition is from EN ISO 472, a norm created by the
European Committee for Standardization (CEN) in August of 2009. They further explain and say
the EN states,
“Plastics are materials that contain an essential ingredient a high polymer and which at
some stage in their processing into a finished product can be shaped by flow. Biomass
means non-fossilized and biodegradable organic material originating from plants,
animals, and micro-organisms. Biomass is considered a renewable source as long as its
exploitation rate does not exceed its replenishment by natural processes” (p. 2).

10

The European definition of bio-based plastic involves some notion of regrowth and
proper management of materials in the last sentence, something missing from the definitions
from the United States (De Wilde & Boelens, 1997). Similar to the Department of Ecology State
of Washington (2014), Kabasci (2014) describes a difference between bio-based and
biodegradable with a few polymer examples. He says, “The process of biodegradation is closely
linked to the molecular structure of the polymer, it does not depend on the origin of the material”
(p. 2). What this means is that some bioplastics are made mostly or totally from fossil fuel based
resources and have the potential to biodegrade, yet some bioplastics made mostly or fully from
renewable resources do not have the potential to biodegrade. Kabasci (2014), like Hottle et al.
(2013) and Talon (2014) provides some example polymers,
“Some fossil-based polymers, like polycaprolactone (PCL) or poly butylene adipate
terephthalate (PBAT) are biodegradable… There are bio-based plastics, like polyethylene
(PE) from sugar cane, which are resistant to biodegradation” (p. 2).

Bio-based is the worst offender for confusing terminology because it does not include
any notion of what potential end-of-life pathway is appropriate. Rather, the term bio-based helps
determine the contents of the bioplastic.

USDA BioPreferred
In the 2002 Farm Bill, the U.S. Department of Agriculture (USDA) launched a program
with the mission to purchase and utilize more bio-based materials within the federal government
to promote U.S. agriculture, create jobs, and reduce fossil fuel reliance. The BioPreferred
program has two initiatives: mandatory purchasing agreements among federal agencies and their
suppliers and a voluntary labeling scheme for those products purchased (USDEWA, 2014;

11

BioPreferred, n.d.). This program is not a standard, but it is commonly and mistakenly used in
those contexts. The USDA BioPreferred program does use a standard created by the American
Society for Testing Materials (ASTM) for determining carbon content, which translates as the
bio-based content of a product. The USDA uses ASTM D6866, which is a test method that can
be used to determine the bio-based carbon content of a material by analyzing a gas after
combusting the material (Narayan, 2014).
The second initiative of the USDA BioPreferred program requires federal agencies to
purchase products with a minimum bio-based content. The content percentage is dependent on
the product. Items like composite plastic building materials, paints, cleaners, even topical pain
ointment are included in the list of 97 products. Topical pain relief products must contain a
minimum of 91% bio-based content whereas plastic lumber is only required to contain 23% biobased content (BioPreferred, n.d.) In addition to federal purchasing requirements, products that
meet the USDA’s minimum requirement for bio-based content are permitted to use the USDA
BioPreferred logo (Narayan, 2014). This logo only indicates the product contains a specific
percentage of bio-based resources, not that it is biodegradable or compostable.
Figure 1.1 USDA BioPreferred Logo

Biodegradable
Biodegradable plastics are materials that “can degrade by naturally occurring
microorganisms such as bacteria, fungi, and algae to yield water, carbon dioxide, and methane,
12

biomass and inorganic compounds” according to a 2014 report by the Department of Ecology
State of Washington. Biodegradable is a common term for polymers that are designed to
decompose, but there is a large discrepancy with the term biodegradable because of the
inconsistent application and the lack of temporal distinction (Emadian, Onay, & Demirel, 2016;
Rudnik, 2008; van der Zee, 2005).
Many bioplastic related groups and organizations have tried to apply a clear definition for
biodegradable. In some context, biodegradable implies hydrolysis, a chemical break down in
water. Alternatively, in non-aqueous contexts, biodegradable indicates fragmentation or
degradation by living organisms. Occasionally biodegradation can wrongfully be suggested as
deterioration, the physical failure of a material (van der Zee, 2005). There are factors inhibiting a
common definition for the international community including: the diverse environments where
the material will be introduced, differences in scientific communities’ determination of
degradation, the variety of consequences on policy, and language barriers (van der Zee, 2005).
In order for biodegradation to have meaning within a standardization context the
environment in which it will decompose must be defined in addition to a measurable time must
be set preemptively (USDEWA, 2014; Rudnik, 2008). Emadian et al. (2016) argue the
conditions of an environment are the key factors for polymer’s degradation including conditions
like the pH, temperature, amount of moisture and oxygen in an environment. Furthermore,
Hermann et al. (2011), state biodegradation can take place in natural or controlled environments.
A natural environment would be in soils or water, where a controlled environment could be a
biological waste treatment like a compost pile or anaerobic digester (Hermann et al., 2011).
Despite the lack of a homogenized definition for biodegradability, all of the efforts have
culminated in a few set elements which van der Zee (2005) outlines,
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“Material manufactured to be biodegradable must relate to a specific disposal pathway
such as composting, sewage treatment, denitrification, or anaerobic sludge treatment.
The rate of degradation […] has to be consistent with the disposal method and other
components of the pathway into which it is introduced.
The ultimate end products of aerobic biodegradation […] are carbon dioxide, water, and
minerals and that the intermediate products include biomass.
Materials must biodegrade safely and not negatively impact the disposal process of the
use of the end product of the disposal” (p.3)
When attempting to define biodegradability it is crucial to understand what it is not. A
plastic labeled biodegradable does not mean it is compostable, recyclable, or entirely made from
renewable raw materials (USDEWA, 2014). Biodegradability is one of the many terms used in
the bioplastic industry to describe a technological advancement in polymer materials.
Nevertheless, the national and international standardization community has created numerous
standards for the term biodegradable. In Table 1.3, the most popular standards are shown.

14

Table 1.3: National and International Standards for Biodegradable Plastics
ASTM D5210-92

Standard test method for determining the anaerobic
biodegradation of plastic materials in the presence of municipal
sewage sludge.

ASTM D5271-02

Standard test method for determining the anaerobic biodegradation of
plastic materials in an activated sludge wastewater treatment system.

ASTM D6340-98

Standard test method for determining aerobic biodegradation of
radiolabeled plastic materials in an aqueous or compost environment.

ASTM D6692-01

Standard test method for determining the biodegradability of
radiolabeled polymeric plastic materials in seawater.

EN 13432-2000

Packaging- Requirements for packaging recoverable through
composting and biodegradation – Test scheme and evaluation criteria
for the final acceptance of packaging.

ISO 14851- 1999

Determination of the ultimate aerobic biodegradability of plastic
materials in an aqueous medium. Method by measuring the oxygen
demand in a closed respirometer.

ISO 14892-1999

Determination of the ultimate anaerobic biodegradability of plastic
materials in an aqueous medium. Method by analysis of evolved carbon
dioxide.

ISO/DIS 148531999

Determination of the ultimate anaerobic biodegradability of plastic
materials in an aqueous medium. Method by measurement of biogas
production.

ISO/DIS 17556-1999

Plastics. Determination of the ultimate aerobic biodegradability in soil
by measuring the oxygen demand in a respirometer or the amount of
carbon dioxide evolved.

All of these standards are standard test methods for biodegradable plastics. They vary by
environment and y all focus on biodegradation. However, only a few have additional evaluation
criteria to determine biodegradability. This is measured by using limits and thresholds. This is
not an exhaustive table, but rather a summary of the most common standard test methods from
The Handbook of Biodegradable Polymers. Adapted from Müller (2005) and Arikan & Ozsoy
(2015).
Table 2.3 is not an expansive list, rather an example to demonstrate the complex and
various methods for standardizing test methods for biodegradation. Narayan (2014) and Arikan
& Ozsoy (2015), provide their own listing of important and common test method standards from
15

ASTM and ISO which overlaps with this table. Narayan (2014) critically points out that these
test method standards “have no pass/ fail criteria, and so should not be used to claim
biodegradability in any environment” (p. 354). Biodegradable standards begin to refer to the endof- life for a bioplastic and this can cause confusion with the term compostable. The terms are
not interchangeable, but it is very common for non-industry members to refer to bioplastics as
biodegradable plastics or degradable. When referring to bioplastics, the term compostable
implies biodegradation, but there are specific details unlike biodegradable (USDEWA, 2014).
Compostable
One of the main elements that separates a biodegradable test method standard from a
compostable test method standard is the requirement of criteria defining pass/fail (Narayan,
2014). Compostable test method standards require the bioplastic to be in a specific environment
for a designated amount of time and demonstrate biodegradation. For a bioplastic to be
considered compostable it is necessary for it to biodegrade in a composting environment (Pei,
Schmidt, & Wei, 2011; USDEWA, 2014). In addition to biodegradation, compostable test
method standards have requirements for disintegration and compost quality (De Wilde, 2005).
Compost quality relates to a compostable plastic’s effect on the compost; it must not leave
harmful residues or impair the compost or subsequent organisms grown in the compost in the
future.
The same organizations that provide biodegradation test method standards provide
compostable test method standards; these include ASTM, ISO, and CEN (Rudnik, 2008). A
bioplastic must meet the three principals of biodegradation, disintegration, and compost quality
in order to pass the test method standards. Most of the standard test methods vary slightly at the
different organizations, but the overall themes remain consistent (De Wilde, 2005).
16

International Organization for Standardization (ISO)
The ISO dominant standard for compostable plastics is #17088. This standard relates
specifically to the “procedures and requirements for the identification and labelling of plastics,
and products made from plastics that are suitable for recovery through aerobic composting”
(ISO, n.d.). Again, the three main components of this test method standard are biodegradation,
disintegration and compost quality. ISO 17088 goes a bit further and distinguishes between
“negative effects on the composting process and facility” and “negative effects on the quality of
the resulting composting, including the presence of high levels of regulated metals and other
harmful components” (ISO, n.d.).
This test method standard lays out the conditions for labelling plastics with the following
three labels:
-

Compostable
Compostable in municipal and industrial facilities
Biodegradable in compost

ISO considers all three of these labels to be equal in definition and purpose. In Table 1.4, the
ISO standards related to compostable plastics are listed. This is not an exhaustive list, but rather
it demonstrates the most common and accepted ISO standards by those involved in the bioplastic
industry.

17

Table 1.4: ISO Standards related to Composting
ISO/DIS
17088

Specifications for compostable plastics.
Environmental labels and declarations.

ISO 14021

ISO 14853

ISO
14855:1

– Self-declared environmental claims.
Plastics- Determination of the ultimate aerobic biodegradation of plastic
materials in an aqueous system. Method by measurement of biogas production.
Determination of the ultimate aerobic biodegradability of plastic materials
under controlled composting conditions. Method by analysis of evolved carbon
dioxide.
– General method.

ISO/DIS
14855: 2

Determination of the ultimate aerobic biodegradability of plastic materials
under controlled composting conditions. Method by analysis of evolved carbon
dioxide.
– Gravimetric measurement of CO2 evolved in laboratory-scale test.

ISO 15985

Plastics- Determination of the ultimate anaerobic biodegradation and
disintegration under high solids anaerobic digestion conditions. Method by
analysis of released biogas.

ISO 16929

Determination of the degree of disintegration of plastic materials under defined
composting conditions in a pilot-scale test.

ISO 17556

Determination of the ultimate aerobic biodegradability in soil by measuring the
oxygen demand in a respirometer or the amount of CO2 evolved.

ISO 20200

Determination of the degree of disintegration of plastic materials under
simulated composting conditions in a laboratory-scale test.

This table represents the standard test methods and their titles from ISO related to composting.
Adapted from Rudnik (2008) in Compostable Polymer Materials.

American Society for Testing Materials (ASTM)
The most common standardization organization in the United States is the American
Society for Testing Materials. Although this organization is recognized outside of the United
States, it is commonly thought of as a regional organization, rather than an international one like
18

ISO (Rudnik, 2008). The ASTM’s most prevalent standard test method for compostable plastics
is ASTM D6400. Below is Table 1.5, which describes the majority of the ASTM standards for
compostable plastics.
Table 1.5: ASTM Standards related to Compost
ASTM D6400

Standard specific to compostable plastics.

ASTM D6002

Standard guide for assessing the compostability of environmentally
degradable plastics.

ASTM D6868

Standard specification for biodegradable plastics used as coatings on paper
and other compostable substrates.

ASTM D6340

Standard test methods for determining aerobic biodegradation of
radiolabeled plastic materials in an aqueous or compost environment.

ASTM D5929

Standard test method for determining biodegradability of materials exposed
to municipal solid waste composting conditions by compost respirometry.

ASTM D5338

Test method for determining aerobic biodegradation of plastic materials
under controlled composting conditions.

ASTM D5988

Standard test method for determining aerobic biodegradation in soil of
plastic materials or residual plastic materials after composting.

ASTM D5511

Test method for determining anaerobic biodegradation of plastic materials
under high solids anaerobic digestion conditions.

This table lists the most common standards related to compostable plastics within the American
Society for Testing Materials. Adapted from Rudnik (2008) in Compostable Polymer Materials.

The scope of ASTM D6400 includes “plastics and products made from plastics that are
designed to be composted under aerobic conditions in municipal and industrial aerobic
composting facilities, where thermophilic conditions are achieved” (ASTM, n.d.). This standard
test method also, like ISO 17088, establishes labeling criteria for the label “compostable in
aerobic municipal and industrial composting facilities” (ASTM, n.d.). To the ASTM this
standard is equivalent to ISO 17088, in that it establishes requirements for satisfactory

19

composting including biodegradation and disintegration although biodegradation is referred to as
mineralization in this standard, but the definitions are parallel.
In addition to biodegradation and disintegration, ASTM D6400 references compost
quality and safety like ISO 17088, but in contrast, ASTM D6400 allows for far greater heavy
metal content in the final compost. In their analysis of ASTM D6400, Rudnik (2008) repeats the
following statement from the standard, “safety of compost must be proved by testing phyto- or
ecotoxicity using methods listed in the Standard” (p. 99). ASTM D6400 does establish
guidelines for compost safety and quality (Philp et al., 2013). While the ASTM D6400 standard
dominates in the United States, the European Union has taken their bioplastic industry a step
further beyond standardization organizations and has passed legislation regarding bioplastics and
the organic recovery of materials (Rudnik, 2008).
European Norm 13432
In an effort to add rigor to existing environmental policies in Europe, the European
Commission (EC) authorized the European Standardization Organization (CEN) to establish
European Norm 13432, which is a “tool to prove compliance with European Directive 94/62/EC
(Rudnik, 2008, p. 99). This norm is recognized by all European Union members and they must
follow this standard, which presents specific criteria and practices for the compostability of
packing; similar to ASTM and ISO. However, this norm exists within the confines of EU
legislation so requirements and consequences have more political meaning than an industry
standard (Lee & Xu, 2005; Pagga, 1998). EN 13432 focuses on packaging, whereas ASTM
D6400 and ISO 17088 focus on additional forms of compostable plastics for other sectors like
agriculture and not solely packaging (Narayan, 2014; Rudnik, 2008).

20

Philp et al. (2013), summarize over 25 standards in their research paper “Bioplastics
science from a policy vantage point” and reiterate EN 13432 as the “Requirements for packaging
recoverable through composting and biodegradation -test scheme and evaluation criteria for the
final acceptance of packaging” (p. 641). Similar to the variety of ASTM and ISO standards
detailing test methods in various environments, European Norms’ 14045, 14046, 14047, 14048,
and 14806 all include specific tests about biodegradation, disintegration, and use methods like
measuring oxygen and carbon dioxide to determine passing criteria (Philp et al., 2013).
Table 1.6 below demonstrates the key differences and similarities between the three most
common compostable plastic standards of ISO, ASTM, and EN. This table, adapted from Rudnik
(2008) provides an overview of the standards used to normalize bioplastics labeled as
compostable plastics. ASTM and ISO are standardization organizations while EN is a European
Norm published from the European Commission.

21

Table 1.6: Compostable Plastic Standards: a Comparison
Standard
ASTM
D6400

Biodegradation

Disintegration

Safety

Single Polymer Products


60% of the organic carbon
must be converted to CO2
within 180 days
Multiple Polymer Products


ISO 17088

90% of the organic carbon
must be converted to CO2
within 180 days

No more than 10% of its
original day weight
remains after sifting on a
2.0 mm sieve after
controlled laboratory
scale composting

Single Polymer Products


60% of organic carbon must
be converted to CO2 within
180 days
Multiple Polymer Products


90% of the organic carbon
must be converted to CO2
within 180 days

No more than 10% of its
original dry mass
remains after sifting on a
2.0 mm sieve after 84
days in a controlled
composting test



No adverse effects on
ability of compost to
support plant growth



Low levels of heavy
metals



Low levels of heavy
metals



A minimum of 50%
of volatile solids



Ecotoxicity
assessment (plant
growth test on 2
different species)
Low levels of heavy
metals



EN 13432

At minimum 90% of
biodegradation within 6 months

No more than 10% of the
residues from the
packaging waste should
be larger than 2 mm



Physical/chemical
analysis of resulting
compost



Ecotoxicity
assessment (plant
growth test on 2
different species)
This table demonstrates the key components of the most common test method standards from
ASTM, ISO, and EN. There are similarities among the 3 categories, like percentages of
biodegradation and disintegration, in addition to low levels of heavy metals. The differences also
lie within percentages of biodegradation and ISO/EN have further safety measures. Adapted
from Rudnik (2008).

In a fact sheet published by European Bioplastics, an association of bioplastic industry
members, they describe the difference between test method standards and the pass/fail criteria.

22

“There are two different types of evaluation systems, which are both commonly called
standards: On the one hand, test methods describe methodological criteria and typically lay out
the procedures that need to be followed. On the other hand, there are specifications, which have a
normative function and define a set of pass and fail criteria as the requirements that need to be
met in order for a product or material to be compliant with the standard.” (European Bioplastic
Fact Sheet, 2016).
It is important to note this distinction because this applies to ISO and ASTM standards, as
well as related European Norms. The labeling of bio-based, biodegradable, and compostable
plastics depends upon the second clause in the above quotation; the specifications and pass/fail
criteria is what determines how products are labeled. Additionally, in the United States, labeling
claims fall under Federal Trade Commission jurisdiction, in addition to the standardization
organizations (Susan Tohman, personal correspondence).
Federal Trade Commission Green Guide (FTC)
The FTC Green Guide is a document which provides examples and is a manual for
making environmental marketing claims about products, packaging, or services in the United
States (Federal Trade Commission (FTC), 2012). This guide is relevant to the bioplastics
industry because it includes information about compostable and degradable claims. The Green
Guides are used to prevent misinformation and false marketing to individuals, businesses, and
groups. According to the first section on the purpose, scope, and structure, “The guides consist of
general principles, specific guidance on the use of particular environmental claims, and
examples” (FTC, 2012). The FTC Green Guides do not have rigorous test standards, but a large
part of the principles includes scientific evidence for compostability and degradability; this
comes in the form of the ASTM and ISO standard test methods.
The compostable claim section in the Green Guide outlines the ways in which marketing
claims using the term “compostable” are able to properly advertise. The first principle states “It
is deceptive to misrepresent, directly or by implication, that a product or package is
23

compostable.” (FTC, 2012, p. 15). The second principal is related to demonstrating proof of the
compostable claim. The guide states,
“A marketer claiming that an item is compostable should have competent and reliable
scientific evidence that all the materials in the item will break down into, or otherwise
become part of, usable compost (e.g., soil-conditioning material, mulch) in a safe and
timely manner (i.e., in approximately the same time as the materials with which it is
composted) in an appropriate composting facility, or in a home compost pile or device”
(p. 16).
The second principle implies a connection to the standardization organizations, but it
does not explicitly state a requirement to use ASTM, ISO, or other standard test methods.
Principle two requires evidence to exist, whereas principle three specifically stipulates that a
compostable claim must include information if the product does not compost without harm or
within an appropriate amount of time in a home compost environment. In addition, the claim
must not be deceptive about the scenario if the product ends up in a landfill that it has
comparable environmental benefits (FTC, 2012). Lastly, the fourth principle relates to
compostable claims and inadequate, industrial or municipal composting facilities. The principle
says a claim must openly state adequate facilities for composting may not necessarily exist where
the compostable product is being sold (FTC, 2012). These principles exist to ensure products
labeled compostable are not deceptive to consumers and the FTC Green Guide provides
examples of claims that are either acceptable or deceptive. An example of an acceptable claim is,
“A manufacturer markets yard trimmings bags only to consumers residing in particular
geographic areas served by county yard trimmings composting programs. The bags meet
specifications for these programs and are labeled, “Compostable Yard Trimmings Bag for
County Composting Programs.” The claim is not deceptive. Because the bags are
compostable where they are sold, a qualification is not needed to indicate the limited
availability of composting facilities” (p. 17).
In addition to compostable claims, the FTC Green Guide outlines degradable claims. The
principles for degradable are similar to those for compostable and includes all claims for the

24

following terms, biodegradable, oxo-degradable, oxo-biodegradable, and photodegradable (FTC,
2012). The second and third principles for degradable claims are similar to the compostable
principles given that they include the requirement of evidence for degradation with temporal and
environmental distinction. A degradable claim made about a product intended for a landfill,
incinerator, or recycling center is deceptive and the FTC Green Guide provides the example of
“A marketer advertises its trash bags using an unqualified “degradable” claim. The
marketer relies on soil burial tests to show that the product will decompose in the
presence of water and oxygen. Consumers, however, place trash bags into the solid waste
stream, which customarily terminates in incineration facilities or landfills where they will
not degrade within one year. The claim is, therefore, deceptive” (p. 18).

The degradable principles in the FTC Green Guide do not intend to establish standards or
test methods, like the ASTM or ISO, but rather they are written guides and principles to prevent
deception for consumers and work alongside standardization organizations to ensure proper use
of the products. In addition to the FTC Green Guide, ASTM and ISO standards there are
certifications for bioplastics which designates approval by a third-party organization.
Overall, these standard test methods and federal guidelines are not influential enough to
be considered regulations and do not provide a great deal of international harmonization. The
varying definitions of bio-based, biodegradable, and compostable remain confusing; however,
certifications and their logos can support the divisions between terms.
Certifications
Certifications play a significant role in the development of bioplastics due to the
industry’s complex, international standards and multitude of stakeholders from manufacturers to
composters. Certifications provide clarity and communicate with consumers about bioplastics by
providing a label or logo that contains meaning about the compostability of a bioplastic (de

25

Wilde, 2005). Along with the ASTM, ISO, and EN standards, there are separate certification
organizations that provide the bioplastic industry with certification schemes. The majority of the
certification organizations utilize ASTM, ISO, and EN standards.
European Certifications
In Europe, the major bioplastic certification organizations are DIN-Certco in Germany
and AIB-Vinҫotte International in Belgium (de Wilde, 2005; Lörcks, 1997). In order to have a
product be certified and printed with the certification label, bioplastic manufacturers must submit
records of evaluations from the standardization organizations in approved laboratories. These
certification organizations in Europe typically base their certification acceptance from EN 13432,
ISO, and ASTM standards. Once DIN-Certco or AIB-Vinҫotte International deliberate and
approve the application, the product receives certification and can bear their logos (de Wilde,
2005; European Bioplastic Factsheet, 2016). These labels are for industrial composting only.
Figure 1.2 from left to right demonstrates the Seedling Logo from DIN-Certco, OK Compost
from AIB-Vinҫotte International, and another DIN-Certco certification DIN-Geprüft Industrial
Compostable.
Figure 1.2: European Certification Logos

Reproduced from European Bioplastic Factsheet www.european-bioplastic.org

26

United States Certifications
In the United States, the largest certification organization is the Biodegradable Products
Institute (BPI). This institute began its certification and logo program by combining efforts with
The United States Composting Council (USCC) in 2000 (Darby, 2012; de Wilde, 2005;
USDEWA 2014). Like its European counterparts, BPI’s certification and logo approval begins
with a submission by a bioplastic manufacturer, the records from ASTM are reviewed, and if
approved, the bioplastic product is certified and able to bear their logo. Figure 1.3 is the BPI
approved logo.
Figure 1.3: United States Certification Logo

Reproduced from www.bpiworld.org

Conclusion
Generally, the test method standards, marketing claims, and certifications attempt to
harmonize and regulate the dizzying variety of bioplastics in the free market, but they lack global
cohesiveness and political clout to truly regulate the industry. This chapter attempted to describe
and explain the most widespread measures for standardizing the bioplastics industry and is a
reference point for the remaining study.

27

Chapter 2: Literature Review
The previous section introduced the standardizations and certifications of the bioplastic
industry. In this literature review, the sections weave together to provide contextual information
on perceptions and knowledge of bioplastics from a consumer perspective and the current
identified environmental challenges of bioplastics. The use of bioplastics began growing in
popularity in the 1980’s when they first appeared on the global market. When first created, they
were marketed for use in the agricultural sector as ground covers or mulch and really became
popular as disposable packaging in the food service industry (Ren, 2003). Around the same time
bioplastics first appeared commercially, awareness of global environmental problems had
intensified and many sociologists argued there was a need to include the environment in social
theory. In the 1980’s, a new theory, Ecological Modernization Theory (EMT), developed out of
earlier European social theory. This study uses EMT to explain the growth of bioplastics and
subsequently the environmental problems of bioplastics within society.
Ecological Modernization Theory (EMT)
In order to understand Ecological Modernization Theory, it is important is to
acknowledge environmental sociology as a subset of the sociology discipline and its focus on
studying the relationships between society and the environment. To some extent, environmental
sociology began with a critique from American sociologists William Catton and Riley Dunlap,
who critiqued what they called the Human Exemptionalist Paradigm (HEP). This paradigm
claimed human beings were acting as if they were free of environmental or natural resource
limitations because of their use of technology (Catton & Dunlap, 1978). To Catton and Dunlap
(1978), this paradigm was a dangerous way of thinking about the relationship between society
and the environment because it ignores the interactions of humans and the environment; it

28

separated ecology and the economy. They theorized a paradigm shift was necessary to change
this and they developed the New Ecological Paradigm (NEP). The New Ecological Paradigm
argues for a paradigm shift that creates a “sustainable management of nature” and “according to
this new exemptionalism, what is needed in the human relationship to the environment is mainly
fine-tuning of the productive apparatus” (Foster, 2012, p. 212).
A few years after Catton and Dunlap published the New Ecological Paradigm, a new
environmental social theory emerged from Dutch scholars Gert Spaargaren and Arthur P.J. Mol
in 1992. Spaargaren and Mol (1992) propose,
“The ecological modernization approach diverges from neo-Marxist social theories in
paying little attention to changing relations of production or altering the capitalistic mode
of production altogether” (p. 336).
Capitalistic modes of production and the environment have been extensively critiqued by
many like Karl Marx, Max Weber, and Justus von Liebig (Foster, 2012). Among the modern
arguments for understanding the foundations of society’s environmental problems is
Schnaiberg’s Treadmill of Production (Spaargaren & Mol, 1992). The treadmill of production
theory focuses its critiques on modernization theory from a post-World War II perspective.
Foster (2012) argues,
“Post-Second World War modernization theory transformed these [capitalism and
Western liberalism] in the process of constructing a rigid, unilinear development model at
sharp variance with the deeper, more probing traditions of classical sociological analysis.
This was particularly evident in its promotion of crude, human exemptionalist notions of
the conquest of nature, in contrast to the most historically mediated, environmentally
conscious views of classical sociology.” (p. 214).
Foster (2012) explains, post-World War II modernization theory led to society’s
ignorance of the environment and its protection, as pointed out by Catton and Dunlap’s (1978)
Human Exemptionalist Paradigm.

29

The Treadmill of Production theory is a “perspective, representing a diametrically
opposite frame [of EMT], rooted in neo-Marxian theory” (Foster, 2012, p. 213). In other words,
Ecological Modernization Theory and the Treadmill of Production are inherently opposite
theories. Given that, Schnaiberg (1980) argues production, as a mode of capitalism, creates and
perpetuates environmental problems because of its fundamental desire to continue economic and
productive expansion. The treadmill model represents modernity circling in place rather than
moving forward, and the only means of moving forward [modernity] and stopping or preventing
environmental problems are slowing or ending the treadmill, also known as deindustrialization
(Schnaiberg, 1980). Overall, Schnaiberg’s (1980) Treadmill of Production theory uses a modern,
post- World War II, Marxist critique of capitalism and production expansion to demonstrate how
these social institutions are the source of environmental destruction and crises.
Spaargaren and Mol are not interested in dismantling the capitalistic relationships
between production and the environment like in the Treadmill of Production theory, but rather
the approach they are interested in modernizes the relationship between the environment and
society. They say,
“environmental problems are not just the unintended consequences of an otherwise
fortuitous trajectory of modernity… their solution is bound up with altering the major
cultural, political, and economic institutions of contemporary society” (Spaargaren &
Mol, 1992, p. 324).
Spaargaren and Mol (1992) disagree with Schnaiberg’s (1980) stance that a single factor
explains society’s overloading of the finite natural resources. Spaargaren and Mol allege that
Schnaiberg focuses on the “monopoly-capitalist character of modern society” and largely ignores
a third characteristic – industrialization- when discussing the environmental crisis (Spaargaren &
Mol, 1992, p.336).

30

Their subsequent Ecological Modernization Theory claims that the “possibility of
overcoming the environmental crisis without leaving the path of modernity” is feasible
(Spaargaren and Mol, 1992, p.334). This implies the path or way of solving environmental
problems is continuing to modernize and grow industrially. The authors agree with Joseph Huber
(1985), whose work founded EMT, and argue that Ecological Modernization is best understood
as a new ecological configuration of production and consumption. Modernizing these two
capitalistic processes through increased technologies aimed at restoring environmental
conditions is the key to change (Spaargaren & Mol, 1992).
EMT is a theoretical framework concerned with the “shift toward technologies that
establish clean production processes”; this means more support for innovations that provide the
environment with advantages rather than damages (Spaargaren & Mol, 1992, p.335). The
introduction of bioplastics as alternatives to traditional petroleum-based plastics can be
considered an example of social change within the Ecological Modernization theoretical
framework. The revolution of industrial processes to produce a consumer product with less
environmental impacts, like reduced natural resource consumption and emissions, is an example
of improved, ecological technologies that work within the existing system’s capitalist market
production.
In this study, EMT is a model for examining and comprehending how society manages
and prevents environmental crisis. In general, theory offers individuals a lens for understanding
the world around them, furthermore this lens influences how and what individuals perceive. This
study is testing Ecological Modernization Theory by analyzing bioplastic use, knowledge, and
perceptions of individuals in Olympia, Washington. Case studies, like this study, are difficult to
generalize. However, the data collected provides insights into the way individuals think about,
31

feel, and experience bioplastics in the environment. By asking about bioplastic use, knowledge,
and perceptions this study challenges the foundations of Ecological Modernization to explain
society’s current attempts to mitigate environmental crisis.
Consumer Awareness and Perceptions of Bioplastics
With any technological innovation, there is concern about the transition from old to new
and bioplastics are no exception. Perceptions about the environmental benefits from bioplastics
are mixed and few scholars have studied reactions to bioplastics entering the market from a
consumer perspective. In a study of 57 Dutch citizens’ perspectives on the bioeconomy,
specifically looking at bioplastics, bio-jetfuels, and bio-refineries, the results were very diverse
(Lynch, Klassen, & Broerse, 2017). The focus group of participants were provided with two
bioplastics products, a bio-based PET bottle and a bioplastic shopping bag with written
information on the location of plastic origin, possible uses, and the end-of life options (Lynch et
al., 2017). The participants offered arguments both in favor and against buying the products. The
authors summarized the arguments in favor of purchasing bioplastics as economic growth for the
country who produces the material, a perceived positive environmental impact, and support of a
green lifestyle (Lynch et al., 2017). Arguments against the bioplastic products included
participants not being convinced of its positive environmental impacts, participants being
confused about how to dispose of the product, the perception that the product was low quality,
the percentage of actual biomass in the bioplastic being low, and an overall concern of
greenwashing and higher prices (Lynch et al., 2017). This study demonstrates the mixed and
highly dichotomous views on bioplastics. The variety of interpretations that exist around
bioplastic’s impacts on the environment and the economy are important to this study because
labeling of these products is directly linked to usage by consumers. Confusion and

32

undistinguishable differences between types of plastics are notable problems within the
bioplastics life cycle.
Sijtsema, Onwezen, Reinders, Dagevos, Partanen, and Meeusen (2016) completed a
similar study to Lynch et al. (2017), but explored a larger sample size. The study looked at five
European countries and the perceptions of 89 participants from Germany, the Netherlands, Czech
Republic, Denmark, and Italy. This study focused on bio-based products and demonstrated the
diversity of perceptions shared by consumers. Sijtsema et al. (2016), provided participants with
seven bio-based products and they were asked to share positive or negative associations. Again,
like Lynch et al. (2017), the results of the study showed strong feelings of uncertainty and many
questions about bio-based products. Sijtsema et al. (2016) concluded that bio-based is a term not
ubiquitous with consumers, so in order to successfully introduce bio-based products in the
market associations with the term should be explored further.
Another study exploring perceptions of bioplastics with Dutch university students and
staff, focused on the characterizations of “natural” and “high quality” materials (Karana, 2012).
This study focused on how perceptions of bioplastics could support product designers and
developers, who are able to facilitate the use of bioplastics rather than petroleum-based plastics.
The results emphasized how materials convey meaning through properties like hardness,
glossiness, elasticity, toughness, strength, weight, opaqueness, warmth, reflectiveness, and
smoothness. These properties are important to the growth of bioplastics because the perceptions
surrounding bioplastics can undermine their effectiveness and contribute to environmental
impacts, especially during the end-of-life stage, explained later by Life Cycle Assessments.
Karana (2012), summarized a few strategies to assist developers and designers in their use of
bioplastics including: introduce bioplastics with a unique look to extrapolate on their differences
33

from petroleum-based plastics; do not use bioplastics as a replacement to conventional plastic,
but utilize their bio-properties in a more holistic design; and move away from purely disposable
bioplastic products to more durable goods to ensure acceptance of the longevity of these plastics.
This is relevant to the present research because perceptions of these products are key to ensuring
they are utilized in the most efficient manner.
Similar to the studies previously mentioned, Magnier, Schoormans, and Mugge (2016)
and Steenis, Herpen, Lans, Ligthart, and Trijp (2017) conducted research related to packaging
and sustainability. In both studies, the researchers were interested in consumers’ perceptions
about the sustainability of product packaging and how consumers reacted to various packages.
They did not predetermine responses for the participants in order to prevent misleading
consumers’ perceptions. Overall, both of the studies came to similar conclusions. Magnier et al.
(2016) discovered that “packaging sustainability positively influences the perceived quality of a
food product” and “individuals make inference about the quality of food products when
assessing a noticeably sustainable packaging” (p. 138). The original question of their study asked
to what degree does packaging sustainability influences consumers’ perceptions of products’
quality and sustainability. Their question relates to this study of bioplastics because bioplastics
are perceived as a sustainable packaging option and if there is evidence of sustainable packaging
influencing perceived quality, it may be in business owners’ best interest to utilize bioplastics or
sustainable packaging to sell their products. Magnier et al. (2016) did not explicitly use
bioplastics, however bioplastics are inherently a part of their study because they defined product
sustainability as,
“the endeavor to reduce the environmental footprint through altering the intrinsic
attributes and thus the composition of the product… In this respect packaging
sustainability is defined as the endeavor to reduce the product’s footprint through altering
34

the products’ packaging, for example by using more environmentally friendly materials”
(p. 132).
This definition is important to this study because bioplastics have been marketed to
consumers as more environmentally beneficial than traditional, petroleum-based plastics. The
environmental benefits of bioplastics are debated and in a study by Steenis et al. (2017) the
intersection of perceived environmental benefits and actual environmental impacts is explored
further.
Steenis et al. (2017), argue one of the strongest influences on modern consumption is
packaging. They argue there is a great deal of effort from packaging companies, lobbyists,
environmental groups, and policy makers to create more sustainable packaging. However, the
most common method for understanding environmental impacts of materials, the life cycle
assessment (LCA), is the least advertised or publicized aspect of packaging, especially to
consumers (Steenis et al., 2017). Life Cycle Assessment measures the environmental effects of a
product. The research investigates the “influences of both the structural elements (materials) and
graphical design of packaging on consumer perceptions of sustainability… Additionally,
consumers’ sustainability perceptions are compared with life cycle assessment outcomes” (p.
287). This study is unique in its application of LCA data because the authors compared
consumer perceptions of packaging, including bioplastics, with the LCA data. This comparison
led to inferences about consumer packaging perceptions and the environmental benefits of the
packaging material. For example, the consumers ranked a bioplastic pot as the most sustainable
of the following seven materials: glass jar, liquid carton, can, plastic pouch, mixed material
pouch, and dry carton sachet. While the consumers perceived the bioplastic pot to be the most
sustainable (ranked first), in terms of the LCA the bioplastic pot ranked fifth, much less
sustainable than perceived by consumers. There are hundreds of LCA’s examining bioplastics in
35

the literature, so this is just one example, but the intersection of LCA and consumer perceptions
is a unique perspective. In general, the authors. Steenis et al. (2017) concluded that consumer
perceptions do not necessarily match with life cycle assessments of products. Therefore, most
consumers use their own beliefs to make decisions about sustainable packaging.
Overall, these studies demonstrate the diverse and often dichotomous attitudes consumers
have related to bioplastics and sustainable packaging. These studies are important to this research
because it makes evident a gap in the literature. In contrast to the studies mentioned, this research
addresses the redistributors of bioplastics, identified as business owners or employees of
businesses who sell their products in or with bioplastics, thus redistributing them from the
manufacturer. Conflicting perceptions of bioplastics environmental benefits become even more
chaotic when the quantitative method for establishing environmental impacts, Life Cycle
Assessment, enters the discussion.
Life Cycle Assessment (LCA)
Life Cycle Assessment is an internationally recognized method for measuring the
environmental effects of a product. Each step in the series of changes that a product goes through
during its entire existence is analyzed. Life Cycle Assessment is one of many life cycle centered
evaluations used by the international manufacturing industry. From the first stages of resource
extraction to the final disposal, or end-of-life, Life Cycle Assessment includes everything a
product experiences (Crisóbal, Matos, Aurambout, Manfredi, & Kavalov, 2016).
Most prevalent literature on bioplastics comes in the form of articles analyzing,
reviewing, or criticizing LCAs of various bioplastics. According to Dietrich, Dumont, Del Rio,
and Orsat (2017), there are other sustainability assessment tools including “carbon footprint,
carbon efficiency, Sustainable Process Index, health and safety score cards, and the Biomass
36

Utilization Efficiency (BUE)” (p. 63). However, Life Cycle Assessment is the most widely
accepted. Here, a Life Cycle Assessment is defined as a tool, which “quantifies the
environmental impact of the entire production chain from biomass collection to either factory
gate or disposal in defined impact categories” (Dietrich et al., 2017, p. 63). Yates and Barlow
(2013) have a bit different definition, and classify LCA as a
“framework which can be used to assess the environmental impacts of a product
throughout its life starting from the extraction of raw materials from the earth and ending
at the waste products being returned to the earth” (p. 55).
Both of these definitions include the notion that a LCA works from earliest beginnings to
the very end-of-life of a material, but Yates and Barlow (2013) include the idea that a LCA
assembles data about both the environmental inputs and outputs, like emissions, waste, resource
consumption and then utilizes this data to transform into widespread environmental impacts. The
outcome of the data assembly and assessment is understood as environmental impacts or
consequences, which translates into anthropocentric concepts like climate change, air quality,
toxicity of humans and ecosystems, eutrophication, and acidification (Yates & Barlow, 2013). In
the 2013 review article Sustainability Assessments of Bio-Based Polymers by Hottle, Bilec, and
Landis, they demonstrate there are LCA guidelines established by the International Organization
for Standardization (ISO). In Table 2.1 below the ISO guidelines are further defined.

37

Table 2.1: ISO LCA Steps
Goal and Scope
Definition
Inventory Analysis
(LCI)
Impact Analysis
(LCIA)

Interpretation

Defines the extent of the analysis including goals and system
boundaries. The functional unit is defined. It describes what is
being studied, how much, and the time frame.
Documents material and energy flows within established system
boundaries. (Inputs and outputs)
Characterizes and assesses environmental effects of data obtained
in the LCI. Expresses the data in common terms like global
warming potential (GWP), eutrophication, smog formation, nonrenewable resource depletion, ecotoxicity, acidification, ozone
depletion, and human health.
Reviews results of LCA, provides conclusions, recommendations,
and identifies areas of improvement.

This table, adapted from Hottle et al. (2013) describes the four steps involved in the ISO LCA
guidelines.
Hottle et al. (2013) point out in addition to ISO’s guidelines, other organizations like the
Environmental Protection Agency (EPA) and the Society for Environmental Toxicology and
Chemistry (SETAC) have adopted guidelines for LCA, but they all contain the same main
themes and are a quantitative analysis. For example, Häkkinen and Vares (2010) interpreted the
four stages of ISO LCA guidelines as
“compiling an inventory of relevant inputs and outputs of a product system; evaluating
the potential environmental impacts associated with those inputs and outputs; interpreting the
results of the inventory analysis and impact assessment phases in relation to the objectives of the
study” (p.1458).
Although they are quantitative in nature, LCAs are open to interpretation of the
researcher and many LCA studies of bioplastics have varying results and analysis (Häkkinen &
Vares, 2010; Hottle et al., 20130; Yates & Barlow, 2013). Beyond the four steps of an LCA,
there are two types: attributional and consequential (Häkkinen & Vares, 2010; Pawelzik et al.,
2013). The attributional LCA, described by Pawelzik et al. (2010) is considered a “causeoriented, descriptive, or retrospective LCA” (p. 224). The attributional LCA utilizes standard and
38

current data to determine environmental impacts; it is specifically looking at the immediate
impacts connected to the life cycle of the material and the system boundaries are restricted.
Häkkinen & Vares (2010) agree and argue “the attributional LCA model does not include
processes outside the life cycle to investigate” (p. 1459).
In contrast to the attributional LCA, the consequential LCA incorporates any process that
is affected by the material’s life cycle (Häkkinen & Vares, 2010). The consequential LCA
according to Pawelzik et al., (2013), “analyzes the environmental impacts based on the
consequences that occur as a result of production, use, and disposal of products” (p. 224). These
LCA’s are aimed more at the effects, change, or potential of a material. The difference in LCAs
is an important distinction for bioplastics because the outcomes of an LCA is highly dependent
on the system boundaries and data collected. For example, Yates and Barlow (2013) review and
analyze nine bioplastic LCAs and four petroleum-based plastic LCAs and found starkly
contrasted viewpoints on the environmental impacts of bioplastics compared to their petroleum
based counterparts,
“Piemonte (2010) found that PLA products had a lower nonrenewable energy use
(NREU) and global warming potential (GWP) than the petrochemical polymer products they
were compared with… In contrast to these results, Hermann et al., (2010) found that PLA used
for both inner and outer food packaging had a greater environmental impact than polypropylene,
the reference material, based on NREU, GW, eutrophication and acidification potential and
ozone creation” (Yates & Barlow, 2013, p. 57).
GWP, NREU, ozone depletion, and the other environmental harms in the above quote are
only a portion of the overall impacts of bioplastics. It is significant to point out the lack of
qualitative and non-numerical data within the LCA framework. This is reiterated by Talon
(2014), who states “LCAs are quantitative studies” (p. 98), and calls for a more holistic analysis
of bioplastics to include qualitative studies and principles alongside LCA’s to account for aspects
of bioplastics that are hidden when examining with a quantitative lens.
39

Environmental Impacts of Bioplastics Determined from Life Cycle Assessment
Overall, the environmental impacts of bioplastics understood from LCA’s can be
categorized by steps in the life cycle, feedstocks, manufacturing & processing, and end-of-life
(Iles & Martin, 2013). Others, like Häkkinen and Vares (2010), explain in terms of inputs and
outputs; inputs are “raw materials, auxiliaries, fuels, electricity, transportation” and outputs are
“products, emissions, wastes, and transportation” (p. 1460). Despite differences in LCA scopes
and system boundaries, there is a general consensus about the major environmental impacts of
bioplastics.
For feedstocks or the renewable natural resources used in bioplastic manufacturing, the
main concerns are based on industrial agriculture issues: land use change, deforestation,
genetically modified organism use, fossil fuel consumption, fertilizer and pesticide application,
eutrophication, acidification, and water scarcity (Álvarez-Chávez et al., 2012; Iles & Martin,
2013). In the manufacturing and processing category the concerning environmental impacts are
focused on fossil fuel consumption, toxic chemical agents used in processing, water use, ozone
depletion, smog formation, and greenhouse gas emissions (Álvarez-Chávez et al., 2012; Hottle et
al., 2013). End-of-life environmental concerns include contamination of recycling facilities,
diversity of environmental conditions at industrial composting facilities which causes ineffective
decomposition, methane release at landfills, and litter, including marine and terrestrial (Hottle et
al., 2013; Iles & Martin, 2013; Yates & Barlow, 2013).
Ecological Modernization Theory (EMT) argues the best pathway out of environmental
crisis is to continue modernizing through technological and industrial growth. With this
interpretation in mind, the environmental impacts of bioplastics can be overcome, and are current
consequences of the attempts to modernize further. This is highlighted in Yates & Barlow’s
40

(2013) critical review of bioplastics LCAs. In their conclusion they say following about the
environmental impacts of bioplastics,
“The current picture is confusing and definitive conclusions are difficult to draw although
the studies reviewed suggest that these biopolymers may not necessarily be more
environmentally friendly than the petrochemical polymers they could replace at this time.
However, trends in studies show that the environmental profile of these biopolymers is
improving and may continue to do so in the future” (p. 65).
The growing demand for bioplastics is a direct call for increased efforts to reduce
environmental impacts, and using EMT to understand the social impacts can be an effective
process for seeing bioplastics as a potential pathway towards ecological modernization.
Conclusion
The literature on Ecological Modernization Theory, perceptions of bioplastics, and their
environmental impacts collectively offer unique, but complementary approaches for
investigating the first research question posed by this study: Are bioplastics less environmentally
harmful than their petroleum-based counterparts? Ecological Modernization Theory provides a
theoretical framework for analyzing the role of bioplastics in economic and social development
toward sustainable modernity. The variety of standards and certifications do not simplify this and
little research has been done concerning standards and perceptions. It is also clear that missing
from the conversation about LCAs is a qualitative perspective. One might draw the connection
that qualitative data absent from LCAs and the various perspectives on bioplastics demonstrates
a need for more research about the role the public’s knowledge and awareness of bioplastics has
in their environmental impacts. This study provides a lens for investigating perspectives,
knowledge, and use of bioplastics and contributes to answering the second research question:
How are bioplastics being perceived and used within the food service industry, their most
common application?
41

Chapter 3: Methods
Research Objectives
The objective of this research is to provide new insights into the attitudes about and the
environmental impacts of bioplastics. This research uses a case study approach, focusing on the
downtown area of Olympia, Washington, using a mixed method exploration of the usage and
knowledge of commercially available bioplastic serviceware amongst food service businesses.
Preceding chapters described the complexities of labeling and certifying bioplastics, their
environmental impacts through Life Cycle Assessment, and attitudes of consumers using
bioplastic products on an international scale. This chapter outlines the methods used in the
empirical research component of this thesis – a study of public perceptions of bioplastics from
the perspectives of the business owners and employees of food service businesses, who are the
main redistributors of bioplastics.
This study fills a gap in the academic knowledge of bioplastics by addressing an
underrepresented population. Most studies exploring perceptions and awareness of bioplastics
focus on consumers. In this context, the term consumer signifies an ordinary citizen who
purchases goods and services (Sijtsema et al., 2016; Steenis et al., 2017). This study differs from
most previous research by focusing on a different part of the supply chain: business owners and
general or purchasing managers. Typically, these individuals purchase bioplastics from a
distributor or wholesaler and then redistribute bioplastics to consumers. This study’s distinctive
method is significant because consumers do not necessarily make the decision to purchase a
bioplastic at food service businesses. The business owner or purchasing manager makes the
decision to procure bioplastic serviceware and redistribute it to customers who purchase food or
beverages at the business. As the literature reviewed in the previous chapters describes, there is a
lack of understanding about how these redistributors perceive bioplastics. The empirical research
42

component of this thesis provides research about a specific population in order to increase
understanding regarding the environmental impacts and perceptions of bioplastics.
Site Description
The city of Olympia, with roughly 50,000 residents in 2014, is located at the
southernmost point of the Puget Sound in western Washington and is the state capital. Olympia
was an appropriate sampling site for this research due to the culture of environmentalism and
progressivism prominent through the city and greater region. It is home to The Evergreen State
College, a self-identified progressive public liberal arts and sciences college. The culture of
environmentalism and progressivism in Olympia is important to this study because residents
were willing and able to speak about environmental issues and express their perspectives on
bioplastics. The culture of Olympia fosters free thinking and encourages residents to be
passionate about reducing environmental impacts. For example, the City of Olympia’s website
includes information regarding sea level rise, resource conservation, zero waste event planning,
environmental education, natural lawn care, and more. Many of the respondents in the interview
portion of this study remarked on the progressive environmental culture of this town. For
example, Respondent #9 said, “I’d definitely say living here, in Olympia, versus many other
places we are way ahead of what other municipalities are offering”. In addition, Respondent #8
spoke of the culture of Olympia and their use of bioplastics. They said, “the motivation for that
[bioplastics] is two-pronged. It’s obviously your market… that’s going to sell here”.
The geographic boundary for the present study was Olympia’s downtown area. Due to
the walkability, and high density of neighborhood restaurants, cafes, and food service operations,
downtown Olympia is an ideal location for this research. The majority of food service operations

43

are locally owned, rather than chains or corporate franchises, providing a unique opportunity to
research the role of bioplastics with local owners, managers, and purchasers.
Sampling and Data Collection Methods
The study used a mixed methods approach comprised of a quantitative survey, as well as
qualitative interviews. The purpose of the survey was to collect baseline data about how and if
food service businesses in downtown Olympia are using bioplastics. Follow-up interviews were
then conducted to garner in-depth answers to open-ended questions connecting environmental
attitudes and Ecological Modernization theory; knowledge of bioplastic products and regulation;
and business decision making regarding bioplastics. The methods for both the survey and
interview process are described below.
Survey
To understand the purchasing and distribution of bioplastics among food service
businesses in downtown Olympia, a survey instrument was developed and included items about
business operations, composting practices, and bioplastics usage. This survey was designed to
collect descriptive statistics about the businesses in downtown Olympia with regard to
bioplastics. Questions on composting practices were included on the survey because the
environmental impacts of bioplastics highly depend on their end-of-life locations. Other
measures included number of employees at the business; whether customers order from a counter
or a server at a table; if the business uses bioplastic serviceware, and if they do use bioplastic
serviceware, what forms and brand names of bioplastics. The number of employees at the
business was included as a reference to the size of the business. The type of food service
business, table service or counter service, was included in the survey instrument because
traditionally, table service businesses have durable or reusable serviceware, whereas counter

44

service businesses generally utilize more single-use and disposable items because their business
model offers convenience and quick service for customers. Counter service was defined as any
business the customer orders at a counter and no servers were present, whereas a table service
business might have a counter option, but the main ordering method was from a server. Please
see Appendix A for the full survey instrument.
These measures directly address the research question: are bioplastics an effective and
environmentally sustainable alternative to traditional, petroleum plastics because they establish
whether or not these products are used at all in downtown Olympia, and more importantly,
whether or not they are used in a way that promotes appropriate use of bioplastics. In this
context, appropriate use ideally means the bioplastic life cycle is a closed-loop cycle and
potentially carbon neutral.
The sample frame for the survey was comprised of all food service businesses within the
boundaries of East Bay Drive, Plum Street, Union Avenue SE, Columbia Street SW, and Market
Street NE (see Figure 3.1). Businesses on both sides of the boundary streets were included in the
sampling frame. These boundaries were determined using Google Maps and the researcher’s
personal knowledge of the location of the highest density of food service businesses in
downtown. If a business was unreachable at the initial walk-in time a second and then final
attempt to conduct the survey was made in person. If no attempts were successful, the business
was not included in the final sample. Additionally, four food and beverage related multinational
corporations within the sampling boundaries were excluded due to the lack of independence
these businesses have individually and the difficulty of reaching a purchasing manager or owner
at the multinational level. The final sample included sixty-three businesses, comprising three
food trucks, six coffee and tea shops, five ice cream shops and bakeries, two specialty food
45

shops, and forty seven restaurants. The final sample represents 75% of all food service
businesses in the downtown area (within the boundaries identified above).
Figure 3.1: Map of Boundaries in Downtown Olympia

Data were collected by a survey strategy modeled off the study by Meeks et al. (2015), in
which audits of grocery stores were conducted in the greater Phoenix, Arizona area. The auditors
visually assessed whether or not bioplastics products were present in a variety of grocery stores.
The present survey was conducted by entering each business in-person, and verbally asking the
46

survey questions from a printed-out form. The present research also employed visual skills to
make observations about bioplastics presence in each business as a backup measure. The study
by Magnier et al. (2016) used an online survey, while others like Sijtsema et al. (2016) and
Lynch et al. (2017) used in-person focus groups. By contrast, the in-person survey method
ensures clarity about certain terms like, bioplastics and composting, in addition to using the
contact for follow up interviews if the business did utilize bioplastic serviceware. Furthermore,
the food service industry is fast-paced and many times phone calls and emails go unnoticed. The
most efficient way of contacting food service businesses is entering during business hours.
Interviews
To address motivations, attitudes, and knowledge of bioplastics semi-structured
interviews were conducted with owners, managers, or purchasers for businesses who used
bioplastics. The interviews addressed the second research question: how are bioplastics being
perceived and used within the food service industry, their most common application? Interview
subjects were identified through the survey – any business that answered “Yes” to the survey
question about their use of bioplastics was asked for a follow-up interview. In total, nine
interviews were conducted, six in person and three over the phone. Interviews lasted 15 minutes
on average and included eight semi-structured questions focusing on why the business uses
bioplastics, how they receive and seek information about bioplastics, and the participants’
knowledge of labeling and standardizations of bioplastics (See Appendix B for the full interview
protocol). Each interview was recorded with the subject’s permission, then transcribed verbatim.
All interviews began by asking about the business operations using bioplastics, then moved to
broader questions pertaining to attitudes and knowledge about bioplastics. The interview
questions were intended to obtain information about the motivations, attitudes, and levels of

47

knowledge about bioplastics, waste streams, environmental impacts, and general experiences
using bioplastics compared to petroleum-based plastics. The questions addressed Ecological
Modernization Theory (Spaargaren & Mol, 1992) by asking business owners and employees
about their role in the free market and bioplastics as a technology advancement. The interview
questions did not overtly ask about EMT, rather they addressed EMT indirectly by inquiring
about standardization knowledge, known environmental impacts, and decision making when
purchasing bioplastic serviceware. The state as an actor in regulation, decision making and free
market capitalism, environmental tradeoffs and technology advancements were anticipated
themes in the questions for interview participants. The expected interview themes address EMT
because they concentrate on the five foundations of the theory. For example, the business owners
and managers participate in capitalism, they are market actors, consumers, and have a strong role
in environmental reform especially through purchasing decisions. Through the purchasing of
new technological advancements aimed at reducing environmental impacts they contribute
examples of EMT as an applicable framework for bioplastics. The results and discussion
chapters delve into these themes further and explore how bioplastics support Ecological
Modernization Theory as a framework for thinking about society and its relationship to the
environment.
Analysis of interview data was a multistep process. Provisional coding was used in this
study, meaning pre-set codes evolved from earlier research and the literature review conducted
by the researcher. The codes were then expanded once the preliminary read through was
completed. The initial coding process for this study used codes informed by literature specific to
the theoretical framework, Ecological Modernization Theory. First, interview transcriptions were
read through one time. Next, the interviews were coded by hand using 12 pre-set themes. The
48

addition of five coded themes occurred after the initial reading and evolved from the researcher’s
interpretation of the interviews. The pre-set themes were: industry knowledge, technology
advancement, pollution concerns, materialism & consumption, depletion of natural resources,
industrial agriculture, composting/end-of-life problems, environmental benefit, environmental
harm, higher costs, marketing/greenwashing, and consumer awareness. The five additional codes
that emerged from the first round of coding were: quality concerns, sustainability & business
integration, policy, local culture, and aesthetic. Finally, a third round of coding focused on
adding more details or clarification to existing codes.
This coding process had similar elements to other studies focused on perceptions and the
environment. In a study of perceptions on illegal marijuana cultivation, Rose, Brownlee, and
Bricker (2016) coded interviews from government administrators, ecologists, and law
enforcement agents without any prior codes, dissimilar to this research. However, the
researchers did place the coded themes into larger generalized categories, similar to the methods
in this study. Rose et al. (2016) also used multiple researchers who coded the interviews
collaboratively, generated themes first, and then applied these themes to more broad categories.
Parts of their method could not work for this particular study because of the lack of multiple
researchers and the attempt to understand this study through the theoretical framework of
Ecological Modernization with specific pre-codes. In another study related to environmental
perceptions, Dutcher, Finley, Luloff, and Johnson (2004), did not use software to code, and used
a priori and posteriori coding process, similar methods to this study. The codes and their larger
categories are shown below in Table 3.1.

49

Table 3.1: Codes by Generalized Category
General
Categories
Pre- Codes

Technology



Technology
advancement
Higher costs

Social





Environmental
Industry
knowledge
Materialism &
consumption
Consumer
awareness
Marketing &
greenwashing








PostCodes




Aesthetic
Quality
concerns





Depletion of
natural resources
Industrial
agriculture
Pollution concerns
composting/ endof-life problems
Environmental
harm
Environmental
benefit

Sustainability &
business
integration
Policy
Local culture

The codes were sorted into larger, more generalized categories to reinforce the theoretical
framework, Ecological Modernization Theory. Spaargaren and Mol (1992) say
“the ecological modernization approach conceptualizes nature or the environment as one
of the two spheres that are threatened by the dynamics of the industrial system, the other
being the life world” (p. 337).
The larger categories from the interview data were created to mimic these spheres.
Social, Technology, and Environmental are interpretations of Spaargaren and Mol’s spheres of
EMT (1992). They are building upon Huber’s (1985, 1989) earlier work where he differentiates
spheres in present society like the sociosphere or life world and technosphere, or industrial
system. Huber (1985, 1989) believes an additional sphere, biosphere or the environment is
necessary to include when analyzing society. The environmental problems faced by modern
50

society are caused by domination of the sociosphere and biosphere by the technosphere
according to Huber (1985, 1989). In order to change there must be reform of the technosphere by
the socio and bio spheres. This change, or environmental reform, is what Huber refers to as
ecological modernization. EMT focuses strongly on the industrial structure of society, not only
the capitalist or production structures, and its interaction with the environment. Overall, the
general themes shadow the spheres as described by Spaargaren and Mol (1992) and Huber
(1985, 1989) to provide additional evidence bioplastics are a suitable example of EMT at work.
Beyond creating the codes and placing them into categories, the next steps of the data
analysis included compiling quotes by respondent. After the last round of coding, the quotes
from all nine respondents pertaining to each corresponding code were compiled into seventeen
separate documents; there was one document for each code or theme. In this way, the prevalence
of the individual codes in each interview was analyzed. The interview and survey results are
discussed in the following chapter.

51

Chapter 4: Results and Discussion
This mixed method study first employed a quantitative survey of food service businesses
in downtown Olympia, Washington, and second, conducted qualitative interviews with nine
respondents from the survey. The findings from the survey and the interviews are presented in
this chapter. The survey results, collected to gain a baseline understanding of bioplastic use in
downtown Olympia, Washington are presented first, followed by the qualitative interview
results.
Results: Survey
The survey gathered sixty-three responses from the eight-four businesses within the
sampling boundaries for an overall response rate of seventy-five percent. There were seven
businesses who chose not to participate and fourteen others could not be reached due to
circumstances outside the researchers control like operating hours. Overall, there were twentyeight table service businesses and thirty-five counter service businesses surveyed. There were
seven more counter service businesses than table service in the sample. Twenty-nine of the
businesses surveyed used bioplastics, and thirty-four did not use bioplastic serviceware, therefore
forty-six percent utilize bioplastic serviceware, while fifty-four percent do not utilize any form of
bioplastic serviceware. Of the twenty-nine businesses who do utilize bioplastic serviceware, ten
were table service and nineteen were counter service. This is shown below in table 4.1.

52

Table 4.1: Bioplastics Use by Business Type
Bioplastics?

Table Service

Counter Service

Total

Yes

10

19

29

No

18

16

34

Total

28

35

63

In addition to business type and bioplastic use the survey gathered data on composting.
The survey provided three answer options, compost with the city of Olympia, compost on their
own, and does not compost. The results are shown below in table 4.2.
Table 4.2: Composting Practices of Businesses
Composting Practices

Total

Compost with the City of Olympia Commercial Organics Program

31

Compost on their own

10

Do not compost

22

Survey Results: Composting
Although no inferential statistical analyses were conducted, descriptive statistics illustrate
the number of businesses who do or do not utilize bioplastics and compare those numbers to the

53

businesses that compost industrially with the city of Olympia, who compost on their own in
home or backyard composting systems, or do not compost in any form thus sending their food
scraps or organic material to the landfill. This comparison is significant due to the ideal end-oflife setting for bioplastics being an industrial or municipal compost. According to the Federal
Trade Commission Green Guide, compostable and biodegradable claims on products must meet
several requirements: one being the claim must not deceive about the end-of-life scenario where
the product will end up. If a bioplastic ends up in a landfill the outcome of that product will be
very different than if a bioplastic ends up in an industrial composting facility. However, there are
issues with composting certain bioplastics, but generally, it is considered best practice to send
bioplastics to industrial composting facilities. Table 4.3 demonstrates that only thirteen
businesses utilize both bioplastic products as well as the city of Olympia composting program.
Furthermore, the same number of respondents do not compost in any form, but do utilize
bioplastic products for a portion of their serviceware. The largest number of respondents,
eighteen businesses, do not use bioplastics in any form, but they do compost with the City of
Olympia program. Seven respondents do not use bioplastics and compost on their own.
Composting on their own represents actions such as saving food scraps and scraping plates for
home compost piles or feed for local livestock. Respondents typically clarified and stated that
bioplastics were explicitly excluded from their compost. The smallest number of respondents use
bioplastics and compost on their own. This might be the case due to the difficulty of separating
wastes of various kinds, like food and serviceware.

54

Table 4.3: Use of Compost with Bioplastics
Bioplastics

Olympia
compost

Own compost

No compost

Yes

13

3

13

No

18

7

9

Total

31

10

22

Survey Results: Table Service and Counter Service
The survey also included whether or not a business was table service or counter service.
As demonstrated in Table 4.1 of the sixty-three total responses, twenty-eight were table service
businesses and thirty-five were counter service businesses. Figure 4.1 demonstrates the
proportion of businesses by type that utilize bioplastic serviceware. Approximately of the
twenty-nine businesses that used bioplastics, one third were table service and two thirds were
counter service businesses. These results were expected since most counter service businesses
are considered fast, casual, and more commonly provide to-go serviceware items, whereas table
service businesses typically use more durable goods and customers dine in the restaurant or
storefront.

55

Figure 4.1: Bioplastic Use by Type of Business

34%

66%

Table Service

Counter Service

Table 4.4 demonstrates the quantity of bioplastics used by businesses in downtown
Olympia. The quantity of bioplastics each business used was separated into four categories. The
categories included one to two bioplastics; three to four bioplastics; five to seven bioplastics; and
eight to ten bioplastics. The largest category across both business type was use of three to four
bioplastic products. Both table service and counter service only had one business utilize eight to
ten bioplastic serviceware products.

56

Table 4.4 Bioplastic Use by Number of Items Used
BIOPLASTICS?

TABLE SERVICE

COUNTER SERVICE

TOTAL

Yes

10

19

29

1 to 2 Bioplastics

3

6

9

3 to 4 Bioplastics

3

7

10

5 to 7 Bioplastics

3

5

8

8 to 10 Bioplastics

1

1

2

Survey Results: Bioplastic Product Form
The survey also collected data on the forms of bioplastics used. The serviceware items
considered were pre-selected for the survey and no respondent had additional types to add. As
shown in Figure 4.2 the most popular form of bioplastic serviceware were cups for cold
beverages. The least common forms, plates and bowls, were only utilized by one business. It is
important to note lids and straws were not as commonly used as cold cups, but many businesses
serve beverages in a cup and include a (traditional plastic) lid and straw. Because of the effects
of heat on bioplastics, bioplastic hot cups are generally not a popular product; this is reflected in
the results. Considering that bioplastic spoons are less desirable for hot items such as soup, their
popularity was relatively high.

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Figure 4.2 Most Common Forms of Bioplastics
20
18
16
14
12
10
8

6
4
2
0

Survey Results: Bioplastic Brand
The survey also asked for brand names of bioplastics. Not every business was able to
give a response; therefore those responses were not included in Figure 4.3 below. There were
fourteen bioplastic brands reported. Earth Choice was the most popular brand with seven
references by respondents, followed by World Centric with five references by respondents. Many
businesses surveyed used multiple brands. For example, one business used eight forms of
bioplastics and at least five distinct brands of bioplastics.

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Figure 4.3 Most Common Reported Bioplastic Brands
8
7
6
5
4
3
2
1
0

Knowing the brand of bioplastics used in downtown Olympia helps address this study’s
research question in a few ways. First, because of the variable environmental conditions of
industrial composting facilities some brands are better suited for disposal in an industrial
compost facility, such as the city of Olympia’s compost program. Second, knowing the brands
can provide more data for connecting the manufacturers, distributors, and composters to improve
processes more holistically.
Survey Results: Number of Employees
Lastly, the survey collected data on the number of employees at each business to serve as
a proxy for ‘size of business’. Table 4.5 indicates there is not a strong connection between the
number of employees and the business decision to utilize bioplastic serviceware items. It was
expected that the higher the number of employees, the more likely a business was to utilize
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bioplastics due to the assumed larger profits and distribution levels. However, the largest use of
bioplastics was from businesses with six to fifteen employees. There were twenty-two businesses
with one to five employees, another twenty-two businesses with six to fifteen employees,
thirteen businesses with sixteen to forty-five employees and six businesses with fifty or more
employees. It is interesting to note that the majority of the businesses within the sampling
boundaries have one to fifteen employees.
Table 4.5 Number of Employees and Bioplastic Use of Businesses
Number of Employees Bioplastics No Bioplastics
1 to 5 Employees

8

14

6 to 15 Employees

10

12

16 to 45 Employees

7

6

50 + Employees

4

2

Conclusion: Survey Results
In this study, the purpose of the survey was to identify potential interview participants of
businesses currently using bioplastics, in addition to collecting data on the popularity of
bioplastics and composting in downtown Olympia. The survey results demonstrated bioplastics
are relatively popular among locally owned and operated businesses, with forty-six percent of
businesses using bioplastic serviceware of some form. Similarly, the city of Olympia composting
program is well used by local downtown businesses, with forty-nine percent of businesses using
the composting program. Due to the properties of bioplastics, in which they decompose at high

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heat, it is not surprising the most common form of bioplastics is cold cups, followed by forks.
Again, not surprisingly bioplastics were used at more counter service businesses than table
service because their business model requires more single-use or to-go items, which must be
packaged. Asking for brand names and number of employees was a part of the survey not for a
hypothesis, but to investigate other factors in business decisions to use bioplastics. Number of
employees did not seem to influence use of bioplastics. However, it is important to recognize in
the sample over half of the businesses fell within the one to fifteen employee range. Therefore,
there is potential that with a larger sample size or different location number of employees might
have an influence on use of bioplastics. Overall, this survey sets the landscape for the following
section detailing the results from the qualitative interviews.

Results: Qualitative Interviews

Unlike the survey methods, the qualitative data for this study was a purposive sample
where only businesses who use bioplastics were asked for participation. The research question of
this study asks about the environmental impacts and perceptions of bioplastics; thus,
necessitating the participation of businesses who use bioplastics. This section delves into the
perceptions and use of bioplastics by employees and owners of businesses in downtown
Olympia. The qualitative interviews were conducted to address the second research question:
How are bioplastics being perceived and used within the food service industry, their most
common application? This section follows the theoretical framework of Ecological
Modernization Theory. As described in the methods section, the nine interviews were coded
using seventeen themes. The themes were then divided into three sections, like spheres in EMT,
technology, environmental, and social. Of the nine interview participants, two represented table

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service businesses and seven represented counter service businesses. The larger number of
counter service representatives mirrors the survey results; the dominant user of bioplastics in the
sampling boundaries is counter service businesses. The results from these interviews contributes
to current knowledge on use and perceptions of bioplastics because the sample was focused on
decision making personnel at each business, whereas previous studies have focused mostly on
consumer use of bioplastics or availability in grocery stores (Lynch et al., 2017; Meeks et al.,
2015; Sijtsema et al., 2016) The findings from the qualitative data are detailed by theme in the
sections below. Interview participants are referred to as Respondent #1, Respondent #2, to
preserve anonymity.
Social Category
In this section, themes from the pre-coding and post-coding are explored further. Social
themes that all nine respondents spoke of include industry knowledge; materialism and
consumption; consumer awareness; and marketing and greenwashing. Social themes mentioned
by some, but not all respondents, include sustainability and business integration; and policy.
Industry Knowledge
The Industry Knowledge theme encompassed what respondents articulated about the
standardizations and certifications of bioplastic products, the transition from traditional
petroleum-based plastics to using bioplastics, and how their knowledge of the bioplastics
industry impacted the transition. Generally, respondents knew very little about the standards and
certifications, but said they did not struggle with the transition to using bioplastics. Respondent
#1 said the businesses transition to using bioplastics became easier over time,
“I would say previously we had looked into bioplastics maybe, I don’t know the exact
time frame, but we had considered it before –looked into pricing and things. It seemed
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too complicated to handle, but anymore they are available everywhere. So, when we did
make the transition it was a simple process for us”.
Respondent #7 spoke of the transition to bioplastics, expressed that they relied heavily on
their supplier and did not know much about bioplastics. “I just called them and said, hey can you
get these [bioplastics] and they were like ‘yes’. I didn’t do too much research on them.”
Respondent #8, who later mentioned they do their own purchasing for the business and do not
use a supplier, discussed the difficulty of researching the bioplastic varieties and said, “It’s tough
to take that time and go “what’s this and what’s that”. Once you do it for two years you kinda
just know and you grab it, but it’s that process of growth and learning”.
After discussion of the transition to using bioplastics participants were asked about their
knowledge of bioplastics and the standards and certifications. Overwhelmingly, respondents did
not know about the standards or certifications and many expressed a wish to know more, but had
only done surface level research. Respondent #2 said of their research process, “In general I
would say Google. I googled bioplastics and fortunately there is a lot of information”.
Respondent #3 stated, “We’ve been looking into making healthy environmental choices even at a
cost for 32 years. We’ve been researching and seeing what’s out there”. They also mentioned a
lack of knowledge. They said, “I don’t know the standards. I’d like to learn more just as a
personal interest” and “as far as certifications and what our manufactures go through for
certifications before they send us products, I’ve never done that”.
Some respondents believed it is simple to find information about bioplastics, while others
disagreed and believed the industry to be convoluted and difficult to fully understand. For
example, Respondent #1 stated, “If you care enough about it to really figure it out, it takes about
two seconds to figure it out. You don’t have to spend a lot of time researching it [standards and
certifications]”. Respondent # 8 stated of their research,
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“I can’t say that I’m an expert, but I understand that if it’s compostable it breaks down in
compost and it becomes something useful. If it’s biodegradable that means that in a
certain amount of time that’s never specified it may or may not return to a state in which
it can. It’s not garbage… you know what I mean? That’s my understanding of it”.
Respondent # 5 expressed a popular theme of the inconsistency seen in the bioplastic industry
and said, “it’s not as uniform as it seems [standardizations]. There isn’t a lot of consistency or
standardization”. Respondent #5 shared a story about speaking with a representative of Thurston
County who discussed with them the difficulties of composting bioplastics. Respondent # 5 said,
“basically, they said that there isn’t a uniform set. There are a lot of testing companies and
certification companies, but nothing that is all encompassing and guaranteed”. To conclude,
Respondent #4 stated “besides knowing it will biodegrade my knowledge of what’s in the
products is limited”.
The respondent’s industry knowledge of bioplastics, including the standardizations and
certifications certainly was not a priority for their purchasing of bioplastics. Only one respondent
mentioned the American Society for Testing Materials (ASTM). While many mentioned using
Google, or relying on their supplier or distributor for information on bioplastics, overall the
general industry knowledge was low.
Consumer Awareness
The second theme all respondents spoke of was consumer awareness. This theme
encompassed their personal knowledge as consumers of bioplastics, in addition to the knowledge
of customers of their businesses. Again, results were mixed on whether or not customers have
any knowledge or opinions on bioplastics. Many respondents spoke of the labeling on the
bioplastics and its influence on their customers. Respondent #1 stated, “I think they [bioplastic
manufacturers] must be also required to let you know that you can’t put them in your kitchen

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compost and expect that to work out for you because that seems to be there as well”. Respondent
#2 mentioned the information on the cups also and stated,
“I do like the information on the cups, and I think people are getting used to looking for
it. And so, it’s allowing the makers to make it a little more hidden I guess. All and all I
would say I really like the labeling and it think it’s doing its job, especially with the
names, ecotainer. They’re using really obvious words”.
Respondent #3 similarly spoke of cups and labeling and stated, “I know that … a lot of our
products say, ‘this is compostable’. That’s what the label says and I understand the gist of like
what materials are used in the products to make them”.
Another important part of the consumer awareness theme for participants was engaging
with consumers about the proper disposal of bioplastics meant for composting facilities. All
respondents expressed difficulty with educating or encouraging customers to understand the
disposal method of bioplastic serviceware products. Respondent #7 discussed the outreach and
education they attempted at their business, “Part of the issue of what we ran into was I was
having to explain to customers oh put your straws in here and put your lids in here and I had
pictures up and it kinda worked”. Respondent #5 also discussed outreach and education for
customers. They said, “We had another difficulty with a lot of our trash cans. Specifically, a can
that says compostables only. You can put as many signs and bells and whistles on any of them
and it just doesn’t relate”. Respondent #3 brought up a different issue. They stated many
customers were concerned with recycled materials and did not know the difference between
recycled content and recyclable. They said,
“Customers haven’t jumped on the compostable bandwagon yet. They want to know why
somethings not recyclable and then when we tell them, well it’s compostable, it will fully
breakdown. Recycling gets kind of complicated. It’s not recyclable, its cups made from
recycled materials, it’s not in turn recyclable. Getting that message out to the customers is
really hard”.

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Respondent #6 discussed the role their employees play in ensuring compostable materials
are going to the correct disposal site. They said,
“It’s hard because it’s definitely one of those things you want to be preaching to the
customers about how to dispose of their item. So, it’s a fine line of what that looks like.
But, I know that our baristas know that they should go in the compost and if they see one
in the bus bin we’re gonna put it in the compost and not in the trash can or the recycling
bin, but outside that, as far as customer education about the product we don’t have much.
Except that we just share it is a compostable item. We don’t want to ostracize them or
make them feel stupid because they don’t know how to dispose of their cup”.

The difficulty in educating customers, while also maintaining status as a business in the
free market was expressed above by Respondent #6 and a few others. Respondent #7 remarked
about educating customers and said, “But I can’t get too righteous because that really turns
people off in this country for some reason. They just don’t like it.” Here, Respondent # 7 was not
only speaking of education about waste disposal, but also single-use plastics and another coding
theme, materialism & consumption. Consumer awareness was interpreted by the researcher in a
few different ways. Included were things like when a respondent mentioned marketing and
education materials prepared by the business, the strategies the business uses to ensure
compostables are disposed of properly, and on the owner/employee side, the knowledge or
awareness the respondent had about bioplastics and their usage. Generally, consumer awareness
focused on the customers of the business and their interactions with bioplastics.
Materialism and Consumption
All nine respondents spoke of ideas or attitudes about materialism and consumption
habits. In critique of EMT, the Treadmill of Production theory directly addresses materialism and
consumption, arguing for a deindustrialization, or a reduction in the production of goods in order
to alleviate environmental problems. Many respondents made statements in favor of reducing

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single-use plastics, using more durable goods, raising awareness about consumption habits, and
the sheer volume of products they use. Respondent #9 stated about their initial use of bioplastics,
“Well I feel like I started out using mainly compostables because I don’t want to contribute to
single use plastic usage”. Respondent #7 expressed discontent about the volume of plastic they
receive from their supplier. They said, “Like the amount of plastic I get covering stuff… Even
covering all those compostable cups. It all comes in plastic bags!” They also expressed their use
durable goods before using bioplastics with their customers, “The goal is to get people to use less
of them and to realize that it comes from somewhere”.
Many other respondents mentioned they typically use durable or reusable serviceware
before using bioplastics. Respondent #6 said, “Typically we try to encourage if people are
sticking around to take it in a glass so that we can just wash it”. Similar to this Respondent #2
stated, “We actually try to limit the use of the compostables and encourage people to use the real
things. The metal- the tasting spoons that are metal”. Others mentioned incentivizing the reuse of
durable goods. Respondent #3 stated, “I know some people like to retain their cup and use it a
few times, bring it back into the store. We give them a discount for their own mug, if they bring
the mug back in”. Respondent #1 did not mention an incentive for customers bringing in their
own reusable goods, however they mentioned how people actually do, “I think, say out of several
hundred people that shop with us a week, we have 2 people who bring a container to put their
things in. Like a glass container, something like that”.

Many respondents voiced concerns about their role in producing waste and their choice to
use bioplastics as a means for lessening impacts of materialism and consumption. Respondent #4
said, “I think the thing is, when you look at the sheer volume of products that restaurants in
general use, if you’re in the position to do anything to sort of mitigate it, I think you should”.
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Respondents were concerned with the waste their businesses generate and many used
bioplastics in an effort to reduce the environmental impacts of their business. Single-use plastics
and disposable to-go items are very prevalent due to customer demand, so many respondents
chose to use bioplastics to mitigate the harms of plastic pollution.

Marketing and Greenwashing
The final theme all nine respondents mentioned during their interviews was marketing
and greenwashing. Most respondents felt good about using bioplastics however, they did not
think bioplastics were without flaws, especially as a product in the free market. The respondents
acknowledged that marketing has a considerable influence on consumer perceptions. Respondent
#1 felt especially strongly about greenwashing and bioplastics. They said about using bioplastics,
“It’s kind of a sore spot with me. Because I think it gives people an excuse to say they are doing
their part [for the environment] when it really counts for nothing. It’s a little bit like sharing a
post on Facebook. I’m not a fan of those”. They continued on to talk about the labeling of the
cup and how it advertises the brand name more than the composting requirements.
“I think the labeling is mostly disingenuous, the labeling will make you feel better about
the plastic cup you have in your hand. If you look closely at the fine print. I think they
must also be required to let you know that you can’t put them in your kitchen compost
and expect that to work out for you because that seems to be there as well. Just always
smaller and harder to come across than the part that tells you what a great person you are
because you are holding a compostable cup”.

Most respondents agreed that they were concerned about greenwashing and corporate
marketing in general. The labeling of bioplastics was particularly mentioned, in relation to
sustainability certifications of all types, including fair trade and organic. Respondent #3
mentioned a lack of control over compostable claims. They said, “If I’m going to sell something
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or serve something that claims to be fully compostable I want to know that it actually is, but I
don’t really have the control over whether it is 100% or not because I don’t work for the
company manufacturing the product”. Respondent #6 expressed concerns about greenwashing
and the uncertainty of what happens to the bioplastics. They expressed the sentiment, “I don’t
know about the grade of compostability, if that makes sense, if it actually composts. We think
we’re doing a great thing, but is it in the right environment to compost as fast as we think that it
is? Or you know if it’s in the landfill. We’re thinking were doing this great thing, but it’s like
lasting just as long”.
Respondent #7 mentioned marketing and greenwashing and the impact it has on business
owners who are looking to provide a specific aesthetic to their business. They said, “I think
labeling is really a sales point for the companies more than it is for the people. There’s the whole
greenwashing bullshit too. That’s what I’m talking about – the hip factor. A lot of people get
forced into it because it serves their customer base”. Respondent #8 was not only concerned with
greenwashing of bioplastics, but other “green” or sustainable labels like organic and fair trade.
They said, “Because the Organic thing- it’s a ticky tacky one. It’s nice in saying, but Mexican
produce has USDA organic, but it doesn’t go through the same inspection process so it’s like
meh… Why do you go to top foods [Whole Foods] and the organic potatoes are on a Styrofoam
sheet with plastic wrap?”. Uncertainty about the bioplastic products and their manufactures was
expressed by almost all respondents. The comment by Respondent #8 demonstrates that it is not
only bioplastic certifications that make consumers weary, but sustainability certifications in
general were mentioned by a few respondents and they overwhelmingly expressed concerns
about validity of certifiers.

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Sustainability and Business Integration
The sustainability and business theme emerged from post-coding and was interpreted as
any efforts or attitudes respondents expressed about trying to reduce the environmental or social
impacts of their business. Not every respondent spoke of this theme, but the majority of
respondents believed sustainability to be a core value in their business. A few respondents spoke
of their business plans or missions. This theme emerged because many respondents did not speak
specifically about bioplastics, but their business as a whole, and how bioplastics played a role in
their sustainability efforts. Respondent #2 said, “We opened the business with the intentions of
always using bioplastics. It’s a part of our mission and actually an integral part of the business”.
Respondent #3 also mentioned a mission of the business, “We have in our company, a guiding
document and one of them is the relationship to our sustainable and environmental footprint”.
Two more respondents mentioned the culture of their businesses and how they strive to make
decisions that cause the least amount of harm to the environment. Respondent #5 said, “We are
constantly looking at ways we can reduce our input, our environmental footprint and be as green
a company as we can from start to finish”. Respondent #6 stated, “We’re a quality of life
company which includes our neighborhood and community so the least amount of waste that we
can put out the better”.

Beyond mission statements and business plans, many respondents commented on a
variety of ways they continue to incorporate sustainability into their businesses beyond using
bioplastics. Composting, buying local produce, and supporting other local farms and businesses
were largely discussed by respondents. Respondent #7 stated, “I try to use more local stuff in the
summertime. I work with a couple of the farms”. Respondent #9 mentioned their business
approach would be lacking if they did not compost or utilize other sustainability initiatives. They
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stated, “I mean a handful of people are like “oh so glad you compost”. It’s not very much, but
you know it kinda goes along with our whole approach to food I think. I think it would be weird
if we didn’t”.

Seven of the nine respondents mentioned their use of bioplastics as an example of the
businesses’ mission to lessen their environmental impacts. In line with EMT, respondents
alluded to the idea that green technologies, like bioplastics, can provide advancement in society
in overcoming environmental crises. Respondent #7 said,
“If they would be incentivized to find a way to make it at a cost and the environment and
they’d be spending science dollars on ways to make it less impactful because it it’s like
“oh well this cup is only going to be on the planet, nothing is just gonna go away”. But if
they can make something that is going to go back into the ground that will maybe be
positive. I’m sure there is a way and there’s science out there. If people get paid to do the
science they’re gonna figure out a way. It a capitalist country, you have to get paid to do
stuff”.
Respondent #8 mentioned their role in society, capitalism and restructuring production
processes to increase environmental focus.
“This is how I choose to participate, by making the best choices and hoping in 5 to 10
years the demand for those products, the oil-based ones, will have disappeared and their
prices will go up because there’s no demand for them. And the demand for these
biodegradable or compostable ones will rise and supply will rise and somebody will be
enterprising”.
They also said, “You can bitch about capitalism all day long. It is here and it is what it is.
And I have kids to feed so I have to participate, no matter what I think about it”. Here,
Respondent #8 is remarking about societal structures and their role as an actor within the
structures.
The above comments were coded as the sustainability & business integration theme
because they directly address business decision making and efforts to reduce environmental

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impacts. The sustainability & business integration theme was created after the first round of
coding because many respondents did not speak specifically about their perspectives on
bioplastics, but rather they spoke about their businesses’ environmental impacts and the tradeoffs
they have to make in business decisions.
Policy
Along with the sustainability and business integration theme, many respondents spoke of
policy at the local and national level and how it influences their business, their environmental
practices, and their decision to use bioplastics or other environmentally conscious factors. On
the local level Respondent # 6 said, “I know Seattle starting in July is requiring that all straws be
compostable. So, I think we’ll probably end up switching back to something like that”. Here,
Respondent #6 is commenting on a local change happening not in Olympia, but Seattle where the
influences of those policies will affect their business’s bioplastic usage. Respondent #7 spoke the
most about policy and even argued for stronger state influence to incentivize production that is
less environmentally harmful; a critique of EMT, which argues state intervention hinders free
market innovations. Respondent #7 says, “If you’re throwing something away that’s
biodegradable in the ground you should be paying less for it, but unfortunately that’s not the way
things are set up in this country”. They went on to say, “We train everybody here [United States]
to make it the cheapest. Who cares about the environmental impact of the thing – which is crazy.
Crazy”. Respondent #7 then suggested their own ideas for how to changes the structures of
society, “If they could incentivize doing it the right way. That’s the tax thing I’m talking about.
It’s such a basic idea. If they could incentivize doing stuff and base it on the long-term effects on
the planet it’s a very simple math equation. And that’s the only thing people in this country can

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understand”. These quotes go a bit beyond bioplastics, but they are directly in line with
Ecological Modernization Theory as envisioned by Spaargaren and Mol (1992).

Technology Category
The second category, Technology, is inspired by the technosphere defined by Spaargaren
and Mol (1992). In this context, the term technology is used as a generalized category for the
following pre- and post-coding themes, technology advancement, quality concerns, and higher
costs. These themes fall under the technology category because they are largely focused on
bioplastics themselves. Bioplastics are an example of a technology advancement, like electric
vehicles, that can provide evidence of Ecological Modernization Theory today.
Technology Advancement
The technology advancement theme emerged in the form of respondent’s discussion of
bioplastics development and recent arrival on the global market. Respondent’s agreed bioplastics
were a novelty compared to traditional, petroleum plastics, but that they still needed more
research and development. Respondent #3 commented on the newness of bioplastics and said, “I
think I would say in the United States it is yet to be fully defined, especially in the compostable,
biodegradable world. There’s still so much research and work to be done. I would classify it,
especially in the beverage world as still a baby, it’s under 10-15 years old really”. Respondent #8
also addressed the difficulty of modern technology, “And with a newer product, or a newer entry
into the field like this it’s not just about balancing the quality. The other difficult part about that
is, at first it was good enough to be biodegradable. And then that wasn’t good enough. Now you
have to be compostable”.

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Respondent #7 spoke about green technology advancement in general, not just bioplastics
and mentioned electric cars and solar as a renewable energy. They spoke of supporting green
technology to build less environmentally harmful products- a main tenant of Ecological
Modernization Theory. They said, “I got solar put on [the building] a couple of years ago and
it’s kind of ludicrous because it literally covers… like maybe a fridge, but I got it because I want
to buy into the industry. I want to buy into that technology”. In addition to solar energy they
mentioned buying into an industry to make it stronger, like electric cars. They said,
“It’s like electric cars, it’s the science you have to buy into because people will tell you
“oh, we’re using all these resources to make these batteries and then what do you do with
the batteries?” And I’m like yeah, yeah, yeah, I get what you are saying, but the point is
that until you continuing on building the… For me it’s like if I buy one that means that
they can continue to make that product better”.
In contrast, some respondents were not convinced that bioplastics will be able to move
society out of environmental crisis. Respondent #9 said, “We’re like “we’re going to figure out
different things that are less bad to use”. Here, they are unintentionally criticizing EMT.
Respondent #9 was discussing how as a society, rather than reducing impacts (i.e. stopping the
treadmill), we continue to solve environmental crisis through advancements in science and
technology, and bioplastics are an example of this.

Quality Concerns
Many of the respondents discussed concerns about quality, specifically the role that
temperature plays in the degradation of bioplastics. This themed was categorized in the
technology category because it directly addresses an issue related to the technological
development of bioplastics. Respondent #4 discussed a problem they had seen with bioplastics
and said, I know if you leave the cups out in the sun they turn to mush”. Respondent #6 also

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mentioned temperature problems and said, “I just think the low temperature threshold, so if it
ends up being warm, if you leave it in your car it melts”. Additionally, Respondent #8 mentioned
the progress they’ve seen in bioplastic technology. They said, “The quality of the product - It’s
gotten better. It used to be everything biodegradable just melted. You put hot food on it and the
boxes would fall apart. But it’s gotten better. It’s gotten usable in the past five years”.

A few respondents spoke of the temperature effects, but understood that temperature
alluded to efficient composting. Respondent #2 said, “The plastics they’re heat sensitive a lot of
times. So, things will melt. Which I kind of like because it just breaks down even quicker”.
Respondent #3 also spoke of issues with warm liquids and the preemptive disintegration of
bioplastics and said, “Our cold cups are made from corn resin and that’s what makes them fully
compostable. You have to make sure it’s all cold liquid in there. It affects the structure of the cup
if you put anything warm in there”. Respondent # 5 made a unique point that no other respondent
mentioned. They stated that failing serviceware could happen with traditional, petroleum based
plastics as well. They said, “There was still the vulnerability that some might fail. Either the
seams, or integrity of the cup, as far as being able to put the lid on. And even with a traditional
plastic cup you can still have issues. If we have a cup that fails, regardless of if it’s a bio cup or a
cup made from fossilized fuel there’s still that risk”.

Higher Costs
All respondents mentioned higher costs, and there was only one respondent with an
opposing viewpoint. When asked about the cons of bioplastics Respondent #4 simply declared,
“They’re just more expensive”. This point was reiterated by Respondent # 7 who stated, “I tried
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to do some research, but it would come down to price. Obviously makes the difference. They’re
a lot more expensive. That’s the hardest”. They continued and gave a price estimate for some of
the bioplastics, “Like a compostable garbage bag is I think like almost 40 cents apiece, as
opposed to a plastic garbage bag is like 5 cents”. When asked about how they chose the type of
bioplastic, Respondent #8 said,
“Price. Absolutely. I wanted to say compostable because there’s a difference between
biodegradable and compostable. We go out of our way to make sure we look for
compostable, but outside of that. Once we reach that place, price is the only thing that
matters to me. Right off the bat it’s 2-3 times more expensive for every piece that goes
out and that’s a crazy consideration for a tiny little business like us”.
Respondent #2 disagreed with the other respondents and said, “Also, it’s really
affordable. In some ways it can be more affordable to use”. Later in the interview, this
respondent changed their mind slightly and said, “It depends on what you are buying, but in
some cases price can be a con”.
Overall, the themes within the technology category directly related to the business
owners or employees’ perceptions of bioplastics. Bioplastics are a relatively new polymer
technology. Thus, quality problems still remain during their use, prices are higher than traditional
plastics, and there is not as much public knowledge about them.

Environmental Category
The environmental category encompasses themes associated with environmental issues in
society. There were no additional environmental themes that developed from the coding process.
The themes are depletion of natural resources, industrial agriculture, pollution, composting/endof-life problems, environmental harm, and environmental benefit.

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Depletion of Natural Resources
The majority of respondents spoke of the depletion of natural resources theme by
mentioning the use of fossil fuels and other raw materials, which is a core concern of Ecological
Modernization Theory. Many spoke about using bioplastics as a means for lowering their
footprint, whether it was their carbon emissions or waste footprint. Respondent #2 said of the
pros of bioplastics in their mind is using less fossil fuels. They said, “One of the pros is definitely
lowering our footprint. Although it does take a lot of energy to still break them down, were doing
the best we can”. Respondent #5 also mentioned their businesses’ footprint and said, “Built into
our business practice is to constantly be looking at ways to minimize our footprint and reduce
our impact”. Respondent #3 mentioned the depletion of natural resources in terms of production
of material goods. They said, “There’s a lot of to-go cups out there just in general. If you do the
math how many people across the world are buying to-go cups every single day and how many
of those end up in the trash every day. Whether they’re compostable or not, is an issue”.
Additionally, Respondent #6 spoke of their choice to use bioplastics because they would not be
contributing as much waste to landfills, adding to their footprint. They said, “We are trying to
lessen the impact that we have globally with our company. So, if we can do something as easy as
switching to a plastic that doesn’t stick around in the landfill as long that’s awesome”.

Some other respondents were not as convinced that bioplastics could lower their
footprint. Respondent #7 questioned the environmental impacts of bioplastics and said, “Then
basically there gets down to a point where they’re saying it takes more power to make the
compostable cups and it still takes 20 years for them to biodegrade and you’re like OK…”
Respondent #9 was also dubious of bioplastics and their fossil fuel usage. They said, “Like if the

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energy you need [for bioplastics] you get from fossil fuel…if it all works out to be more earth
friendly, I would assume. I would hope it’s not a big scam”.
The most common way respondents spoke of the depletion of natural resources theme
was fossil fuel use, carbon or waste footprint, and the manufacturing of goods. Bioplastics were
seen both as a product with the potential to reduce impacts to natural resources, but some
respondents were not convinced bioplastics might contribute negatively to natural resource
depletion.

Industrial Agriculture/Pollution Concerns
A limited number of respondents spoke of specific environmental concerns related to
bioplastics production and manufacturing like industrial agriculture and pollution. Although, the
interview questions were aimed at exploring environmental attitudes and perceptions, only four
respondents mentioned industrial agriculture. Of the respondents who discussed industrial
agriculture, Respondent #2 mentioned the use of corn for bioplastics, “I know corn is used, that’s
a big problem crop, I can only imagine. I don’t really know what’s out there for that”.
Respondent #5 discussed feeling better about bioplastics if they knew where the renewable
resources were derived from. They said, “If it’s coming directly from a genetically modified corn
product or if it’s coming from biomass of husks and stalks. If we had some clarity in where the
actual product was coming from”. Respondent #6 also questioned the renewable resources to
produce bioplastics, like corn. They said about their products, “It is a corn based cup. Like, what
is the environmental impact of monocrop and a bunch of extra corn being grown and processed?
I don’t know the environmental impact of that”. Respondent #8 expressed concerns about corn
as a feedstock for bioplastics, specifically the genetically modified species of corn. They said,
“And now, oh well those are made from corn and corn is mostly GMO, you’re supporting
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GMO”. It can kinda become a cluster”. Due to the difficulty of knowing where and what a
bioplastic’s feedstock is, many respondents have concerns about the industrial agricultural
practices used to produce them.

Most respondents made general comments about industrial agriculture being harmful to
the environment and did not know enough to feel comfortable expanding on the subject.
Pollution concerns were few and far between in the interviews. However Respondent #7 did
mention water pollution from chemicals used to wash durable good or serviceware and how they
did not know which was better: using single-use items or durable ones. They said about washing
and reusing their cups, “It takes water which is a very finite resource. A chemical to wash this
cup that I’m flushing down the water drain to wash this cup, so it’s not even close to perfect”.

Composting/ End-of-Life Problems
Composting and end-of-life problems were the most common environmental theme
discussed by respondents. Numerous respondents voiced distress about whether or not the
bioplastics are composted and their intended end- of-life disposal, in addition to concerns about
the actual decomposition or biodegradation of the plastics. Respondent #3 was discussing their
role in distributing the products and said, “So if things aren’t going through the proper channels
to be taken care of [compost, rather than landfill or recycling] it’s a moot point to begin with”.

Respondent #9 also spoke of concerns about if bioplastics are ending up in composting facilities
and how composters are handling the products. They said, “And that I don’t know…How
composting facilities… Like how much non-food can they take?”. Composting and end-of-life
disposal for bioplastics serviceware is highly dependent upon the actions of the customer.

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Respondents communicated a concern with leaving end-of-life decisions to the customer.
However, they did not feel strongly about their role in changing behaviors.

Environmental Harm
This theme was used for any statements made from respondents about general harms
caused by bioplastics or other products, or systems within society. Respondents spoke of singleuse plastics, compost contamination, fossil fuel, increasing waste, and Styrofoam. Respondent #3
spoke of the environmental harm caused by packaging. They said, “That’s an issue, with how
much packaging for food and beverage that human beings throw away every day. If it’s not
addressed in a really serious matter it’s going to become a big problem in our landfill”. The
environmental harms of Styrofoam were mentioned by a few respondents. Respondent #7, who
uses only uses bioplastics or paper products for their service ware said, “Then you still go to
places where they’re still using Styrofoam for everything. So, you’re like what the hell?”

Respondent #5 touched on concerns they had about bioplastics being harmful to the
environment. They listed questions they had about bioplastics and the environmental harms that
can evolve from their use. They said, “When you are utilizing plastic from a source that is also
considered a food source, I mean there are several things – is it being composted? Are people
throwing in and mucking up the recycling systems? Is it safe?”. Overall, environmental harms
are present in all materials created for society and the respondents who spoke of environmental
harms agreed there was not one material, bioplastic, or traditional plastic that was the definitive
best choice; they did agree Styrofoam was the most environmentally harmful material.

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Environmental Benefit
Many respondents shared the perception that bioplastics were an environmental benefit.
One respondent said, “I mean, I don’t see any reason not to use it [bioplastics]. I know there’s
people still using Styrofoam”. Styrofoam was mentioned in a few of the interviews, and most
respondents believed that Styrofoam was an environmental harm and bioplastics were a
beneficial solution to reducing environmental impacts from packaging. Respondent #5 said, “But
thankfully we’re not in the Styrofoam cup era”. Again, the use of bioplastics as a replacement to
historically destructive materials, like Styrofoam, was seen as an environmental benefit. One
respondent generally stated of their decision to utilize bioplastic serviceware, “Again, I can’t
reiterate it enough. It’s the right choice, and it’s a good choice. You know we’ve got to start
somewhere”. Largely, respondents articulated the environmental benefits of bioplastics
outweighed the harms, thus supporting their use of bioplastic serviceware products.

Discussion
The primary purpose of this research was to first provide a detailed overview of the
standard test methods, certifications, and federal guidelines, then collect baseline data about
bioplastics use through a quantitative survey, and lastly conduct qualitative interviews about the
knowledge and use of bioplastics in downtown Olympia, Washington to gain a deeper
understanding of perceptions about these ecologically innovative products. The survey results
offer descriptive statistics of what types and how many businesses are using bioplastics, what
forms are most common, are businesses using bioplastics and composting, how many employees
do businesses have that use bioplastics, and what bioplastic brands are commonly found in
downtown Olympia. A little less than half of the survey participants used bioplastics. The
majority of businesses that used bioplastics were counter service operations with one to fifteen
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employees. Commercial composting is common in downtown Olympia and thirty-one of the
sixty-three participants utilized the city of Olympia’s commercial organics composting program.
Overall, the survey gave insights into the distribution of bioplastics in downtown Olympia.
Subsequently, the qualitative interviews provided a deeper understanding of the
perception and level of knowledge about bioplastics among professionals in the food service
industry. Generally, interview respondents expressed mixed feelings about their use of
bioplastics, similar to other studies asking consumers about their perceptions (Sijtsema et al.,
2016). Although, most participants did speak to their use of bioplastics as a means for
incorporating the environment or sustainability into the business practices. Most participants
shared the belief that using bioplastics was the right thing to do in order to mitigate their
environmental impacts. All but one of the businesses represented by the nine interview
participants either composted with the City of Olympia or on their own, further supporting their
efforts to reduce environmental impacts.

The heart of this research analyzes whether or not, bioplastics offer a less
environmentally harmful solution to their traditional, petroleum-based counterparts. The
qualitative data presented in this study demonstrates that the redistributors of bioplastics in
general have strong positive attitudes toward bioplastics. However, hesitations and doubts also
exist owing to the complex structures surrounding bioplastics, such as the ambiguous and
unregulated standards and certifications; uncertainties of compost facilities ability to decompose
bioplastics; vague environmental claims of reducing greenhouse gas emissions or other
environmental damage; and bioplastics inability to replicate traditional, petroleum-based plastics
in price and quality. It is clear bioplastics have the potential to be an ecological innovation as

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suggested by Ecological Modernization Theory, but EMT only offers a way of thinking about
innovative products and environmental crisis. The bioplastic industry is a global force with many
complexities.
The research in this study supports Ecological Modernization Theory because it
demonstrates bioplastics are a prevalent, new green technology that many utilize because they
feel bioplastics cause less environmental harm than their traditional, petroleum-based
counterparts. The first two core foundations of Ecological Modernization Theory state first,
science and technology may have caused environmental problems, but conversely, research and
development provide a path to overcome and prevent future environmental crisis; and second, all
market actors play a role in environmental reforms, not just state agents and governments
(Spaargaren & Mol, 1992). The proliferation and demand for bioplastics via businesses in the
free market embrace these two foundations, supporting Ecological Modernization Theory.
Increasing demand of bioplastics by market actors, like local businesses, will lead to an increase
in their supply and demonstrated by the qualitative interviews, these market actors generally
perceive bioplastics to be environmentally beneficial.
However, like Ecological Modernization Theory, the bioplastic industry is not without
flaws. Scarce federal regulation, varying industry standards and certifications, in combination
with the dissociation of producers and manufacturers of bioplastics with end-of-life composting
facilities has led to complications that weaken Ecological Modernization Theory as a useful
framework for understanding the relationship between society and the environment. Ecological
Modernization Theory claims when dealing with environmental regulation, less command-andcontrol style policies lead to environmental reform. In the example of bioplastics there is very
little governmental regulation or policy which has led to a wide variety of industry standards and

83

certifications policing the industry. In order to reform bioplastics to be an authentic green
technology, it may be necessary for federal regulation to be implemented. According to
Schnaiberg (1980), EMT places too little emphasis on the role of state institutions and
exaggerates the positivity of free market dynamics. During the qualitative interviews, a few of
the respondents indirectly criticized EMT and expressed the attitude that a shift in federal
regulation must occur for bioplastics to truly become an environmental benefit. Nevertheless,
Ecological Modernization Theory, is just that: a theory for examining the relationships between
society, its institutions, and the environment.

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Chapter 5: Conclusion and Recommendations

Bioplastics were created with the intention of existing as an alternative to petroleumbased plastic to mitigate harmful environmental impacts like pollution and fossil fuel
consumption. Although the creation of bioplastics may have been altruistic, the environmental
benefits of bioplastics are not necessarily as they seem. The numerous problems surrounding
bioplastics and their manufacturing, utility, and proper end-of-life treatment are discussed within
the qualitative interviews detailed in this study, demonstrating that public knowledge of
bioplastics is mixed.
The problems with bioplastics are highly systemic issues related to industrial agriculture
and waste management policies. For example, if the practices of using pesticides and fertilizers
in industrial agriculture were reformed to cause less damage to the environment, bioplastics may
have an opportunity to reduce their environmental impacts.
The two-pronged data collection method used in this research attempted to provide a new
approach to understanding environmental impacts of bioplastics. By reaching out to the middle
user group of bioplastics, this study sought out the key stakeholder in society’s interactions with
bioplastics. The data collected suggests most of these middle user groups recognize their role in
redistributing these products to customers, however they lack resources to change systemic
problems hindering bioplastic’s ability to alleviate the environmental harms of tradition,
petroleum-based plastics. At its core, the research question asked in this study is about trade-offs,
and pros and cons of bioplastics. By collecting quantitative data on the use of bioplastics
amongst food service businesses in Olympia, Washington and following up with qualitative
interviews, this research adds to the literature on bioplastics. This research provides results that

85

other researchers can build upon and include both quantitative and qualitative data to holistically
understand bioplastics.
This study attempted to address a lack of research on a specific user-group of bioplastics
and provide descriptive statistics in a case study setting. There are several limitations that must
be noted. For example, using downtown Olympia as a case study constrained the survey sample
size and interview participants to a specific geographic and cultural context, resulting in nongeneralizable outcomes. Second, the qualitative interviews only included participants from
businesses that were using bioplastics, rather than from businesses that both did and did not use
bioplastics. This is limiting because it restricted perspectives on bioplastics solely to those who
utilize them, resulting in a potential for biased responses. Only interviewing participants from
businesses that used bioplastics emphasized why businesses utilize them, but this study lacked
data on why businesses do not use them.
The limitations of this study indicate determining if bioplastics are less environmentally
harmful than their traditional, petroleum-based counterparts is not simple. This study has strived
to expand the literature on the perceptions, knowledge, and use of bioplastics. In conjunction
with the peer reviewed literature, this study suggests that further research of the bioplastic
industry is necessary. For example, more research on best practices for end-of-life disposal in
real life, how and where bioplastics are being utilized, and environmental assessments that not
only employ quantitative data, but brings together both quantitative and qualitative methods.
Finally, more research is needed on how to effectively communicate between every step in a
bioplastics life cycle

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Bioplastics evolved out of a social desire to create a more sustainable plastic material.
They use less fossil fuels, are derived from renewable feedstocks, contain properties for
biodegradation, and can be fully composted. Bioplastics are a product of free market innovation,
which suggests bioplastics are an appropriate and valid example for the theoretical framework
used for this study, Ecological Modernization Theory. Bioplastics are growing on the global
market and are expected to reach a market value of 30.8 billion dollars by 2020 (Bhilare, 2018).
Many argue that bioplastics provide a viable option in combatting environmental crisis.
However, bioplastics are not without flaws; this study identified areas of environmental concern,
as well as problematic industry standardizations and certifications. This study also concentrated
on a case study example to understand the perceptions and knowledge of bioplastics of
professionals in the food service industry where bioplastics are most common, but largely this
study aimed to demonstrate EMT as an applicable way of thinking about the role bioplastics
have played and will continue to play in modern environmental reform.

87

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Appendices
Appendix A: Survey Questions

Name of Business

________________________________________

Type of Business (circle one)

Counter Service

Table Service

Combination

Number of Employees
________________________________________
Does this business compost through the City of Olympia commercial organics collection? (circle
one)

Yes

No

Does this business compost without commercial pick-up? (circle one)

Yes

No

Not including paper or wood products, does this business purchase bioplastics, also known as
compostable plastic packaging, to use in foodservice? (circle one)

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Yes

No

What forms of bioplastics are used? (Circle all that apply)

Forks

Knives

Spoons

Hot Cups

Lids

Straws

Take-out Containers

Bags

Cold Cups
Sample/ Portion Cups

Plates

Bowls

What is the brand and/or type of bioplastic?

________________________________________

________________________________________

________________________________________

In the company, who is the most appropriate person to follow-up with for an interview regarding
bioplastics and compostable plastic? This typically would be an owner, purchaser, or employee
in charge of purchasing supplies.

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Appendix B: Interview Questions

1. What was the transition to using bioplastics like?
2. How did you choose the types of bioplastics for this business?
3. Could you tell me about some reactions or responses from customers about your use of
bioplastics?
4. In your mind, what are the pros of bioplastics?
5. What are the cons, if any?
6. Can you tell me what you know about the labeling of bioplastics?
7. Where did you find this information?
8. If any, what environmental concerns do you have regarding bioplastics?

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