Are Bioplastics a Better Environmental Choice?
By Anja
Krieger
 |
| It's still trash |
Many people assume all bioplastics are made from plants and can break down completely in the environment. But that’s not the case.
The
term “bioplastics” is actually used for two separate things: bio-based plastics
(plastics made at least partly from biological matter) and biodegradable
plastics (plastics that can be completely broken down by microbes in a
reasonable timeframe, given specific conditions).
Not all bio-based plastics are biodegradable, and not all biodegradable plastics are bio-based. And even biodegradable plastics might not biodegrade in every environment. Sounds confusing? It certainly is.
Not all bio-based plastics are biodegradable, and not all biodegradable plastics are bio-based. And even biodegradable plastics might not biodegrade in every environment. Sounds confusing? It certainly is.
“There
are a lot of bioplastics or materials that are called bioplastics that are not
biodegradable,” says Constance Ißbrücker, head of environmental affairs at
the industry association European Bioplastics.
For some plastics, the same polymer chains can be made from renewable sources. The resulting bioplastics are chemically identical to their fossil counterparts.
PET, for example — short for polyethylene terephthalate, which is the stuff most bottles are made of — can be synthesized from fossil fuel products or plants like sugarcane. The resulting material is the exact same. Such non-biodegradable bioplastics behave in the environment just like conventional plastic and persist for an unknown but long amount of time.
Not
only that, but none of the standards for plastics labeled as
biodegradable or compostable today makes them suitable for disposal in the open
environment. Given that, can bioplastics play a role in tackling environmental
problems? Or are they merely greenwashing? The most accurate answer is, it
depends.
PLA:
Conditionally Compostable
Because it can be derived from plant material like corn sugar, potato or sugarcane, it can reduce the demand for fossil fuels used to make conventional plastics.
PLA
is recyclable, biodegradable and compostable. But that doesn’t mean the
ocean — or any other natural environment — can easily handle it.
To Frederik Wurm, a chemist at the Max Planck
Institute for Polymer Research (MPIP), drinking straws made from PLA are “the
perfect example for greenwashing.” They are more expensive than other plastic
drinking straws, but don’t readily biodegrade on a beach or in the sea.
“You
put it on the package [that it] is biodegradable, but at the point where these
materials are . . . fear[ed] to end up, they will not biodegrade,” Wurm says.
For
biodegradation, PLA needs industrial composting conditions, including
temperatures above 58 °C (136 °F). It needs to be properly managed and
routed to specialized industrial composting or recycling facilities.
Under the right circumstances, microbes can turn the material into carbon dioxide and water within a couple of weeks. However, if it becomes littered or dumped, PLA sticks around for much longer. When pure PLA ends up in seawater, it does not seem to biodegrade at all.
Under the right circumstances, microbes can turn the material into carbon dioxide and water within a couple of weeks. However, if it becomes littered or dumped, PLA sticks around for much longer. When pure PLA ends up in seawater, it does not seem to biodegrade at all.
PHA: It’s
Complicated
Other
kinds of bioplastics are known to better biodegrade in marine environments.
However, whether that really happens in a specific case, and how long it will
take, is highly unpredictable.
Marine
biologist Christian Lott and his colleagues at HYDRA,
a private research institute with a research station on the Italian island of
Elba, have field-tested different biopolymers in a range of aquatic
environments from tropical beaches to the Mediterranean seafloor.
They found that materials that had been shown to biodegrade in seawater in lab testing also do so in the environmental conditions they tested.
They found that materials that had been shown to biodegrade in seawater in lab testing also do so in the environmental conditions they tested.
Among
the materials tested at HYDRA are bioplastics called polyhydroxyalkanoates
(PHAs). Produced by microbes, PHAs currently comprise a tiny
slice of the market. However, demand is expected
to grow strongly in the next few years.
A
thin film of PHA will degrade in a tropical environment on the seafloor in one
to two months, Lott says. But in the Mediterranean, it can take 10 times as
long.
“And imagine, in the Arctic, in the ice or at ice-cold water, or in the deep sea where we have 0 to 4 degrees, hardly any nutrients around, bacteria will have a hard time to digest these materials,” he says.
“And imagine, in the Arctic, in the ice or at ice-cold water, or in the deep sea where we have 0 to 4 degrees, hardly any nutrients around, bacteria will have a hard time to digest these materials,” he says.
This
is the caveat to PHAs, says Linda
Amaral-Zettler, a marine microbiologist at the Royal
Netherlands Institute for Sea Research (NIOZ). “While they can biodegrade
in the marine environment, we still need to appreciate that part of the marine
environment is not compatible with biodegradation.”
In
some regions of the ocean biodegradation is so slow that even organic material
like fish or algae can leave their traces in the fossil record.
“Life
is complicated,” Lott puts it, “and it’s about life — because it’s
bio-degradation.”
Super-Biodegradable?
Even
with the best waste management systems, it’s realistic to assume some plastic
will always escape.
Think of the abrasion from car or bike tires, from ship paints, sneakers, or synthetic garments. If bits of plastics are small enough to travel through the air, they will be hard to ever contain.
Think of the abrasion from car or bike tires, from ship paints, sneakers, or synthetic garments. If bits of plastics are small enough to travel through the air, they will be hard to ever contain.
So
could we design a plastic that breaks down pretty much anywhere?
Wurm
says it would theoretically be possible to build molecular triggers into
materials so that they know when to biodegrade.
“It sounds fancy, and it is fancy and it’s expensive,” he says. But even if the funding were there, finding and including molecular triggers for each and every material in each and every environment seems to be a nearly impossible task.
“It sounds fancy, and it is fancy and it’s expensive,” he says. But even if the funding were there, finding and including molecular triggers for each and every material in each and every environment seems to be a nearly impossible task.
A
material that has a full functionality but biodegrades immediately at its end
of life, is “not going to happen. Never,” Lott says.
Different
Chemicals, Different Problems
Moreover,
when considering the impacts of plastic products on humans and the environment,
looking at just the plastic itself is never enough. A single plastic
product can contain dozens of chemicals, some of which might have adverse
effects on us humans or other organisms if they are released into the
environment and taken up.
Lisa
Zimmerman, a Ph.D. student in the Department Aquatic Ecotoxicology at Goethe
University in Frankfurt (Main), Germany, has conducted research that suggests
that chemical mixtures present in biodegradable or bio-based plastic products
can influence the metabolic activity of the bioluminescent bacterium Aliivibrio
fischeri.
In a number of additional experiments she found that these chemical mixtures can have the potential to cause oxidative stress or influence the hormonal system in living organisms.
In a number of additional experiments she found that these chemical mixtures can have the potential to cause oxidative stress or influence the hormonal system in living organisms.
“What
I can tell from my research is that bioplastics are not necessarily safer than
conventional plastics with regard to the toxicity of the chemical mixtures they
include,” Zimmermann says.
Land Use
Issues
Bio-based
plastics have other environmental implications as well. One big criticism has
been the land needed to grow the plants.
On
the basis of a report from the Institute for Bioplastics and
Biocomposites (IfBB) in Hanover, European Bioplastics estimates that
bio-based plastics currently use less than 0.02 percent of
agricultural land. “There is no real competition with food and feed
production,” Ißbrücker argues.
But
Christoph Lauwigi, who represents the working group on waste and resources with
Friends of the Earth Germany (BUND) worries about the side effects of a growth
in the bioplastic market.
In the German Plastic Atlas, he explains that an increase in bio-based plastics could raise the pressure on arable land, potentially leading to water shortages, desertification and the loss of habitats and biodiversity.
He also notes that the reliance on industrial agriculture for the production of new plastics might increase monoculture cropping and the use of pesticides.
In the German Plastic Atlas, he explains that an increase in bio-based plastics could raise the pressure on arable land, potentially leading to water shortages, desertification and the loss of habitats and biodiversity.
He also notes that the reliance on industrial agriculture for the production of new plastics might increase monoculture cropping and the use of pesticides.
Ißbrücker
says the industry is working toward a smaller land use footprint by using waste
materials or algae. At this point however, these sources cannot be processed as
effectively yet as the current feedstocks, she adds.
Niche
Applications
Plastics
that are currently marketed as “biodegradable” will themselves contribute to
plastic pollution if they are lost or littered.
They do not break down as quickly and completely in the environment as the term might imply and can thus harm wildlife and ecosystems. But there are a few applications where using biodegradable plastics may provide a net benefit to the environment.
They do not break down as quickly and completely in the environment as the term might imply and can thus harm wildlife and ecosystems. But there are a few applications where using biodegradable plastics may provide a net benefit to the environment.
In
some countries, bags that are compostable under industrial conditions are used
to collect organic waste. They can offer a cleaner and more convenient way than
nondisposable containers for people to collect food scraps for composting.
Enzo Favoino, a waste management expert at the
Scuola Agraria del Parco di Monza in Italy and chair of the Scientific
Committee of Zero Waste Europe, is convinced this is the way
to go.
Fewer organics in the trash means less fermentation, allowing waste management operators to come by less often to pick up the trash. This can not only save money but also boost the recycling rates of other materials such as paper, glass, plastic and metal, he says.
Fewer organics in the trash means less fermentation, allowing waste management operators to come by less often to pick up the trash. This can not only save money but also boost the recycling rates of other materials such as paper, glass, plastic and metal, he says.
Collecting
organic waste separately also diverts food scraps from landfills and dumps,
where they can produce methane — a powerful greenhouse gas contributing to
climate change.
However,
not every country has the infrastructure in place to use compostable bags to
these ends. In Germany, for example, compostable bags are screened out of the
organics by technology that doesn’t distinguish between compostable and
conventional plastic.
Biodegradable
plastics are currently also marketed as mulching films for agriculture,
which farmers can just leave on the fields to plow under.
For decades, plastic mulch film has been spread out on fields to support crop growth and save pesticides and water. But with conventional plastics this so-called Plasticulture can cause “white pollution” to accumulate on farmland if it is not removed and discarded.
For decades, plastic mulch film has been spread out on fields to support crop growth and save pesticides and water. But with conventional plastics this so-called Plasticulture can cause “white pollution” to accumulate on farmland if it is not removed and discarded.
Is
biodegradable film a safe alternative? If they are proven to biodegrade in the
soil, they would leave less pollution behind.
But wind or animals might carry pieces of broken film into the air, rivers or oceans, to places where they might not be able to biodegrade. There’s also a potential for chemicals to leach from the films to the soil ecosystem, a question that is currently under scrutiny.
But wind or animals might carry pieces of broken film into the air, rivers or oceans, to places where they might not be able to biodegrade. There’s also a potential for chemicals to leach from the films to the soil ecosystem, a question that is currently under scrutiny.
Tackling
Confusion
There’s
no doubt, bioplastics are still plastics. Just because some of them are made
from plants or have the potential to biodegrade under limited conditions, they
can’t be touted as “planet-safe.” For the ones that claim to biodegrade or
compost, the fine print is crucial.
So
check the label: What does it say? Where and how is it supposed to biodegrade?
How can you safely dispose of the product? 5 Gyres,
a California-based nonprofit working on plastic pollution, has published an
overview of labels in its Better Alternatives Now B.A.N. List 2.0.
Beware, however: According to Ißbrücker, some uses of labels are fake.
Beware, however: According to Ißbrücker, some uses of labels are fake.
Finally,
be cautious when you read that a material is oxo-biodegradable. These
are conventional plastics like polyethylene mixed with metal compounds that
make them fall apart faster.
According to a report by the United Nations Environment Programme (UNEP), it hasn’t been proven that they truly biodegrade, and it is feared they might just accelerate microplastic pollution.
Similarly, European Bioplastics warn that so-called “enzyme-mediated degradable plastics” aren’t truly biodegradable.
According to a report by the United Nations Environment Programme (UNEP), it hasn’t been proven that they truly biodegrade, and it is feared they might just accelerate microplastic pollution.
Similarly, European Bioplastics warn that so-called “enzyme-mediated degradable plastics” aren’t truly biodegradable.
Reduction
Remains Key
The
plastic industry projects strong growth in production, while many
environmentalists are calling to reduce use.
Biodegradable
plastics won’t solve the plastic crisis, so tackling consumption remains key.
“By just reducing the amounts and the types of different packaging that we have
in our supermarkets, we can do a lot, without developing novel materials,” says
Wurm.
Even
European Bioplastics’ Ißbrücker thinks that might very well happen. “Maybe not
in 5 or 10 years, but as the problems keep growing, plastic production might go
down one day, because it’s just too much.”
A transcript and more episodes of the Plastisphere
podcast are available here. A German version
of this article can be found on RiffReporter.
Anja
Krieger is a freelance journalist based in Berlin,
Germany. She's the creator and producer of Plastisphere, the podcast on
plastic, people and the planet. She holds a graduate degree in cultural
sciences and is an alum of the Knight Science Journalism Fellowship program at
Massachusetts Institute of Technology.
