Overview
ABSTRACT
The article presents the different key-steps in the life cycle of biobased and/or biodegradable polyesters. It describes the preparation methods of each of these polyesters, going back to the raw materials used, especially when these are of plant origin. The main functional properties and current or future applications are detailed and criticized with regard to the issues of today. Their strengths but also the obstacles limiting their development are explained. The end of life of these polyesters is examined by focusing the end of life scenario towards recycling for non-biodegradable polyesters and towards (bio)degradation for biodegradable polyesters.
Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.
Read the articleAUTHOR
-
Stéphane BRUZAUD: University Professor - Université Bretagne Sud, Institut de Recherche Dupuy de Lôme, - UMR CNRS 6027, Lorient, France
INTRODUCTION
Since the beginning of the 21st century, interest in polyesters has been driven by current environmental concerns. Indeed, some of them can be biosourced (totally or partially), i.e. synthesized from renewable resources derived from biomass, and also biodegradable. The polymer is considered biodegradable if it is capable of leading in fine, through combined chemical and biological processes, to a mixture of water and carbon dioxide in an aerobic environment (or methane in an anaerobic environment). At present, despite exceptional growth in biosourced plastics of the order of 20% per year, the plastics industry's dependence on fossil resources remains overwhelmingly preponderant, since around 99% of plastics are of petrochemical origin. Dependence on this single resource can have long-term economic, ecological and political consequences. Although opinions still differ on the kinetics of fossil resource depletion, there is no doubt that fossil resources are becoming progressively scarcer, and so the need to find alternatives through the use of renewable resources arises. At the same time, it seems essential to develop production technologies such as plant-based biorefineries, which have less environmental impact than petrochemical processes responsible for significant greenhouse gas emissions. As for the end-of-life of these plastics, which are the subject of countless attacks due to poor waste management and their negative impact on the terrestrial and marine environments and on ecosystems, we need to look at the ways in which polyesters can be re-used, through various strategies such as composting or recycling. The various recycling mechanisms include mechanical recycling, as traditionally used for polyethylene terephthalate (PET), but also emerging recycling routes for PET or polylactide (PLA), such as chemical or enzymatic recycling. The (bio)degradation of polyesters, particularly in different environments (freshwater, seawater, domestic or industrial compost, soil, etc.), is now well documented in the literature, which shows that the biodegradation behavior of polyesters is drastically modified according to their own physico-chemical characteristics (intrinsic factors), as well as according to the environments studied (extrinsic factors).
The study and development of new polymeric materials of renewable and/or biodegradable origin, such as polyesters, therefore represent a major scientific and environmental challenge for academic research, as well as for the chemical and plastics industries. Polyesters are a fascinating family of polymers insofar as their end-of-life scenarios are very advantageous, since they can be processed by recycling (mechanical, chemical and even enzymatic) or biodegraded (in industrial or domestic composting, or even in the natural environment if necessary),...
Exclusive to subscribers. 97% yet to be discovered!
You do not have access to this resource.
Click here to request your free trial access!
Already subscribed? Log in!
The Ultimate Scientific and Technical Reference
KEYWORDS
recycling | biodegradation | polyesters | elaboration | properties
This article is included in
Functional materials - Bio-based materials
This offer includes:
Knowledge Base
Updated and enriched with articles validated by our scientific committees
Services
A set of exclusive tools to complement the resources
Practical Path
Operational and didactic, to guarantee the acquisition of transversal skills
Doc & Quiz
Interactive articles with quizzes, for constructive reading
Biosourced and/or biodegradable polyesters
Bibliography
Websites
Author's personal web page: research projects, press articles, online conferences, interviews, etc.
https://www.irdl.fr/annuaire/stephane-bruzaud
EUROPEAN BIOPLASTICS: data on biosourced and/or biodegradable plastics
...Directory
The PolyBioAid association offers its members an online library on biosourced and/or biodegradable polymers containing some 3,100 different publications, totalling 184,000 pages and weighing 70 GB. E-mail: [email protected]
Standards
- Plastics-Thermoplastic biodegradable mulching films for use in agriculture and horticulture – Requirements and test methods - NF EN ISO 17033 - 01-2018
- Standard test methods for determining the biobased content of solid, liquid and gazeous samples using radio analysis - ASTM D6866 - 2014
- Plastics – Determination of the aerobic biodegradation of non-floating plastics in a seawater/sediment interface - NF EN ISO 19679...
Exclusive to subscribers. 97% yet to be discovered!
You do not have access to this resource.
Click here to request your free trial access!
Already subscribed? Log in!
The Ultimate Scientific and Technical Reference