Litcius/Paper detail

Regenerative Textiles: A Framework for Future Materials Circularity in the Textile Value Chain

Miriam Ribul

2021Sustainability16 citationsDOIOpen Access PDF

Abstract

Materials science breakthroughs have regenerated high value fibres from end-of-life cellulose-based textiles that can be introduced into existing textile fabrication processes from raw material to textile product in established textile value chains. Scientific developments with regenerated cellulose fibres obtained from waste textiles suggest their potential to replace virgin resources. The current scale-up of regeneration technologies for end-of-life cellulose-based textiles towards pilot and commercial scales can potentially achieve a future materials circularity, but there is a lack of a long-term view of the properties of materials after consecutive recycling stages take place. Cellulose-based materials cannot be infinitely recycled and maintain the same quality, a factor which may provide new challenges for future textile processes in the context of the circular bioeconomy. This paper maps collaborative design and materials science projects that use regenerated cellulose obtained from waste feedstock according to materials in the value chain they seek to substitute. It also presents four new processes that use regenerated cellulose materials in relation to their intervention in the value chain (as determined in a PhD investigation). A framework is presented to demonstrate how these circular material design processes take place at earlier stages of the textile value chain after subsequent regeneration stages.

Topics & Concepts

TextileRaw materialContext (archaeology)CelluloseRegenerated celluloseRegeneration (biology)Supply chainCircular economyEngineeringMaterials scienceBiochemical engineeringNanotechnologyProcess engineeringWaste managementPulp and paper industryBusinessChemistryComposite materialChemical engineeringEcologyMarketingCell biologyOrganic chemistryPaleontologyBiologyAdvanced Cellulose Research StudiesAdditive Manufacturing and 3D Printing Technologiesbiodegradable polymer synthesis and properties