Substantia. An International Journal of the History of Chemistry 5(2): 35-39, 2021

Firenze University Press 
www.fupress.com/substantia

ISSN 2532-3997 (online) | DOI: 10.36253/Substantia-1287

Citation: Campanella L., Suffritti G. B. 
(2021) Can non-recyclable plastic waste be 
made environmentally sustainable?. 
Substantia 5(2): 35-39. doi: 10.36253/
Substantia-1287

Received: Apr 12, 2021

Revised: Jul 19, 2021

Just Accepted Online: Jul 20, 2021

Published: Sep 10, 2021

Copyright: © 2021 Campanella L., Suf-
fritti G. B. This is an open access, 
peer-reviewed article published by 
Firenze University Press (http://www.
fupress.com/substantia) and distributed 
under the terms of the Creative Com-
mons Attribution License, which per-
mits unrestricted use, distribution, and 
reproduction in any medium, provided 
the original author and source are 
credited.

Data Availability Statement: All rel-
evant data are within the paper and its 
Supporting Information files.

Competing Interests: The Author(s) 
declare(s) no conflict of interest.

Feature Articles

Can Non-Recyclable Plastic Waste Be Made 
Environmentally Sustainable?

Luigi Campanella1, Giuseppe B. Suffritti2

1 Dipartimento Chimica, Sapienza, Università di Roma, Roma, Italy
2 Dipartimento di Chimica e Farmacia, Università degli studi di Sassari, Sassari, Italy
E-mail: luigi.campanella@uniroma1.it; pino.suffritti@gmail.com

Abstract. After death the fraction of living matter which is not biodegraded (shells, 
bones, corals, carbonaceous deposits) becomes environmentally sustainable. This is 
not the case for plastics so that these wastes should be either recycled or made envi-
ronmentally inert and stored in secure repositories as a resource for future genera-
tions. Chemistry has offered different solutions to this problem, and each brings about 
advantages and disadvantages when compared to other options. One further possible 
route could consist in the enrichment of the plastics waste in carbon content (“carboni-
zation”), in analogy with the production of charcoal from wood, but we hope to stimu-
late a debate about all the other possible routes among scientists and engineers in the 
involved fields. 

Keywords: plastics waste accumulation and dispersion, circular economy, carboniza-
tion of plastics waste.

1. INTRODUCTION

There is a growing concern about the accumulation and dispersion of 
plastics waste.1-4 Plastics have become indispensable for human life and for 
industry, but their high chemical stability makes most of them not complete-
ly degradable when dispersed in soil, fresh and sea water, and in air, unless it 
was properly designed to be biodegradable. Most plastics are obtained from 
fossil oil,up to about 10-12 % of the global production, according to an IEA 
report published in 2018.3 Even using the best plastic waste management 
practices,5-9 models predict that an important fraction of plastics waste (more 
than 22% in 2050) will accumulate,10 especially in surface water and oceans, 
reaching a mass of 500±100 Mt in 2050.3 

In oceans these wastes are able to create true plastic islands, that reached 
in 2018 an overall surface of 1.6·106 km2, corresponding to about 6 times the 
surface of France, in the Pacific Ocean only.3 Plastics waste degradation is 
accelerated by irradiation from the UV component of sunlight and by some 
mechanical wearing, with the continuous production of smaller and smaller 
debris, maintaining a substantial chemical integrity.11-17 Energy recovery as 
heat, steam, or electricity by burning plastics wastes, that in 2016 represented 

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36 Luigi Campanella, Giuseppe B. Suffritti

the fate of as much as 40% of plastics waste,3 is strongly 
discouraged because of the production of greenhouse 
gases and pollutants.1-3,13 As it will be better detailed 
below, different strategies have been proposed for reus-
ing and recycling plastics waste,18 but its large fraction 
that accumulates in landfills and, what is much more 
dismaying, in surface waters and oceans, is generally 
not adequately considered. Although we are not pure 
specialists in the field, general common sense considera-
tions led us to give our little contribution to drive the 
attention of the scientific community of chemists to this 
important problem in order to be allowed to say “I do 
my part of the job”

2. CIRCULAR ECONOMY AND PLASTICS WASTE

There are several different ways to define circu-
lar economy. According to the European Commission’s 
Implementation of the Circular Economy Action Plan, 
approved in 2019, Circular Economy is: 

A system aimed at eliminating waste, circulating and 
recycling products, and saving resources and the environ-
ment.19

In a recent review focused on the plastics waste, it is 
stated that:9

[the] concept of “circular economy” (CE) commonly refers 
to the “take-make-use-break-make” concept, where the 
main goal is to create economic impetus from the waste. 
It also enables the close-looping of product – waste – 
building block cycle.

However, as remarked for instance by Kümmerer 
et al.,5 a complete recycling of plastics waste is practi-
cally impossible, unless plastics materials are purposely 
designed, and in fact a huge amount of wasted plastic 
residues is actually dispersed in the environment. 

A closer look at natural living systems action to 
maintain environmental sustainable cycles can give 
some further insight in extending the concept of circu-
lar economy. Indeed, after completing their vital cycle, 
the fate of living matter “waste”, besides a small quan-
tity of volatile compounds, which are dispersed in the 
atmosphere, water or in soil, is mostly bio-recycled. Only 
a negligible fraction of it is burned as a consequence of 
natural events, such as fires caused by lightning, or by 
volcanic eruptions. However, a more or less important 
fraction of living matter waste is made of mineralized 
remnants. For instance, bones buried in soil last nearly 
unchanged for centuries, shells of aquatic animals are 

accumulated in lakes, seas, oceans floors and eventually 
become rocks, and coral colonies are able to build up 
entire islands. Finally, fossil carbonaceous deposits (coal, 
oil and natural gas) were originated by large amounts of 
living matter deeply sunk in soil. All these long-lasting 
living matter wastes share the important property to be 
environmentally sustainable, or inert. In conclusion, the 
natural ecology is not strictly circular, but the produced 
“waste”, which is not recyclable is environmentally sus-
tainable. Therefore, it is reasonable to ask ourselves why 
we cannot follow a similar route for the management of 
plastics waste, by proposing that all what cannot be bio-
degraded or used as feedstock for recycling18 shall be 
treated to become environmentally inert and stocked in 
secure repositories, for future use as matter and energy 
resource.

3. OVERALL MANAGEMENT OF THE PLASTICS 
WASTE

Plastics often consist in one or more co-polymers 
along with several additives such as plasticizers, flame 
retardants, coloured agents, ultraviolet-light stabilizers, 
antioxidants that are difficult to separate during the recy-
cle process leading to waste of time, money and material. 
The bottleneck of recycling is the preliminary separation 
and fractionation of the present compounds. Therefore 
recycling is often considered only at the atomic or molec-
ular level with possible loss of the intrinsic properties of 
the products compared to those of the same products in 
the original waste. In January 2018 the European Com-
mission announced a vision for Europe’s new plastics 
economy substantially based on a new model of econo-
my: from linear to circular economy. So the following 
commitments are considered to be implemented:
– all plastic packaging used in Europe must be reused 

or recycled by 2030;
– more than half of the plastic wastes must be recy-

cled;
– plastic sorting and recycling capacity must be 

extended fourfold by 2030:
– some 10 million tons of recycled plastics are to be 

used for new products by 2025.
Mechanical recycling consists in transforming the 

plastic waste in raw material without any substantially 
modification of its chemical structure. It is the largely 
most adopted method in Europe but due to the pres-
ence of additives the process cannot recover more than 
60-70% of the original wastes. The recycled materials 
find the same application as the original plastic wastes, 
in any sector of our today common life. 



37Can Non-Recyclable Plastic Waste Be Made Environmentally Sustainable?

If separation and filtration of additives is omitted to 
save time and money, the obtained products are mainly 
used in mixed formulations applied to building works 
such as streets, bridges and other infrastructures. An 
alternative way is based on a selective dissolution of the 
plastic waste followed by filtration and evaporation of 
the solvent, but the real innovative process of recycle is 
based on chemical and biotechnological processes espe-
cially applied in the case of wastes of polyethylene tere-
phthalate (PET), nylon and polyurethane. Among the 
chemical processes, pyrolysis consists in heating under 
vacuum which will result in a final product that con-
tains a mixture of liquid and gaseous hydrocarbons.4,20-23 
De-polymerization can be obtained, at least for PET 
by means of microwave radiation.24 Hydrogenation is 
a degradation that involves a treatment with hydrogen 
followed by heating, and in this case the products are 
olefinic hydrocarbons (ethylene, propylene, butadiene). 
Gasification is obtained by heating at high temperature 
(800-1600 °C) in the absence of air that results in a mix-
ture of hydrogen and carbon monoxide. Chemolysis, 
glycolysis, methanolysis, amminolysis are all de-poly-
merisation processes that produce low molecular weight 
products, which can be used as reagents of multiple syn-
thetic reactions and represent an alternative route, that 
results in the formation of chars (solid carbonaceous 
materials) and gaseous hydrocarbons. However, these 
solutions do not contribute to the “decarbonisation” of 
our society: the products are intended to be used as fos-
sil fuels so contributing to further increase the anthro-
pogenic greenhouse effect.

An innovative way of recycling is the enrichment of 
plastics wastes in C content. This process leads also to 
the recover of hydrogen and other heteroelements. The 
final products can be stored in the same sites where the 
raw material was extracted, such as exhausted carbon 
mines and fuel deposits, reproducing a stock of inert raw 
material to be used in the future.25

The main problem of this option is to have the prop-
er catalyst able for the extraction of hydrogen and other 
elements similarly to what was obtained with the char-
coal from the thermal treatment of wood. As recently 
reported, a catalyst based on mixed iron and aluminum 
oxides acting under a microwave field of 1000 W seems 
to be able to extract hydrogen from plastics. 

Also biotechnological methods were successfully 
applied to the recycling of plastics.6 The discovery made 
by a group of researchers of Carbios and of the Toulouse 
Institute of Biotechnology26 of an enzyme present in the 
leaves’ compost has opened a new way to recycle PET 
with very promising results as the recycled material has 
the quite same properties of the original waste.

In the 25th August 2020 issue of the Chemistry 
World weekly Kyra Welter reports that an International 
Group of research was successful in obtaining a poly-
mer able to be recycled in principle for an infinite num-
ber of times, during which it was depolymerized and the 
obtained monomer was re-polymerized and so on.27,28 
Contrary to mechanical recycling that changes the prop-
erties of the material after few cycles, monomerization 
can potentially bring to materials that can be recycled 
whenever needed without any limit and keeping the 
same properties of the raw starting material. The prob-
lem in this case is that monomerization, if not purposely 
designed for plastic materials is not an available chemi-
cal process.

The chemical modification of the existing hardly 
recyclable plastics can increase their lifetime and face 
three different problems: first, in general polymers easily 
decomposed do not present good properties; second, the 
obtained products behave better in many common appli-
cations; and, third, if one wants to have good mechani-
cal properties for the new product it is necessary to 
control the stereochemistry of the polymerization. The 
integration of this option in the actual recycling systems 
could be difficult because of the multifarious variety of 
the plastic waste, increasing the number of the possi-
ble components. This point can only be solved by a very 
responsible behavior of citizens and of local Institutions.

In general, plastics waste treatment can entail a net 
cost, which is to be supported in view of the unbearable 
environmental damage of accumulation and dispersion of 
plastics waste.4 In line with a recent proposal about car-
bon taxes, this cost should be recovered from special ad 
hoc taxes “similar to a value added tax (VAT) [...] such 
that end users pay the full costs.”.29 Indeed general taxa-
tion usually is not equally charged and distributed among 
taxpayers.30 Note that actually many megatons per year 
of plastics waste are exported from Europe, Australia and 
North America to China and other countries,3,4 entail-
ing transport costs that could be avoided if sustainable 
domestic treatments are properly implemented.

4. DISCUSSION AND CONCLUSIONS

In this paper we shortly outlined some dismay-
ing problems connected with the management of plas-
tics wastes, and particularly, of the large fraction of this 
waste which is accumulated untreated in landfills as well 
as in surface and sea waters, even if an increasing com-
mitment is advanced to reuse and recycle plastics waste 
by the various available procedures.1 Any effort and 
strategy should be performed to avoid the dispersion of 



38 Luigi Campanella, Giuseppe B. Suffritti

plastics waste in air, waters and soil, by securing and 
controlling any phase of deposit, and especially in the 
long-lasting landfills. 

As remarked, in view of the global warming prob-
lems, it should also avoided and restricted any treatment 
of plastics waste releasing CO2 and other greenhouse 
gases into the atmosphere. In addition, the products 
of plastics waste recycling suitable as fuels should be 
preferably if not mandatorily used as feedstock for the 
chemical industry, so sparing mineral oil resources, or 
stored in secure repository. 

A general strategy for the plastics waste manage-
ment was proposed in the conclusions of a recent review 
about microplastics (tiny specks of plastics of microm-
eter size) by Hale et al.:13

Most plastics are inexpensive to manufacture. Hence, 
there is little financial incentive to reuse them. To sup-
port a circular lifecycle, the upfront price of plastics must 
incorporate end of life costs. Currently, low volume plastic 
users and associated ecosystems bear a disproportionate 
burden (e.g., remote islands are now being littered with 
plastic debris). This environmental injustice echoes that of 
climate change and sea level rise. Landfills may be mined 
by future generations as resources become scarce and 
technologies improve. Optimization of such “dumps” into 
“repositories” is worthy of consideration. Political initia-
tives across borders should seek to accomplish these goals.

However, by considering the amounts and the rate 
of accumulation in landfills, in our opinion it is urgent 
to find also sustainable technical routes to transform the 
untreated or not recyclable plastics waste into “inert” 
matter which should be stored in secure repositories, 
such as exhausted mines of coal and other minerals, or 
impermeable quarries, as a resource for future genera-
tions. It could be objected that a large fraction of plas-
tic waste is already environmentally “inert”, as it lasts 
almost unchanged for hundreds or even thousands of 
years,14 if properly saved. There are at least two reasons 
to propose a further treatment of plastic waste. First, the 
chemical nature of plastic materials makes their use as a 
feedstock in the future rather difficult and expensive, so 
that saving more homogenous materials would be pref-
erable. The second reason is that the recovery of hydro-
gen, fluorine and other elements could help in reducing 
or even offset the cost of the treatment. In addition, the 
danger of a dispersion of degraded plastics in air and 
waters (especially as microplastics) would be contrasted, 
and the amount of the final waste could be reduced. All 
this can be obtained by the enrichment of the plastics 
waste in C content (“carbonization”). Examples of chem-
ical processes that can achieve this result are discussed 
by Chen et al.25

If this proposal is considered unpractical or too 
expensive, we wonder whether there are there other ways 
to obtain environmentally sustainable materials from 
plastics waste.

In conclusion, on one hand, we urge scientists and 
engineers working in the field of plastics materials to 
think and propose practical solutions to this problem, 
and on the other hand we hope that a fruitful discussion 
about the ways to avoid accumulation and dispersion of 
plastics wastes will involve a larger scientific, technologi-
cal, political and especially social public. 

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	Substantia
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