Litcius/Paper detail

Green, recyclable, mechanically robust, wet-adhesive and ionically conductive cellulose-based bioplastics enabled by supramolecular covalent hydrophobic eutectic networks

Mengqing Li, Hongzhuang Zhang, Yizhi Gong, Zhulan Liu, Ren’ai Li, Yunfeng Cao

2023International Journal of Biological Macromolecules13 citationsDOIOpen Access PDF

Abstract

The development of novel cellulose-based bioplastics (CBPs) is highly desirable because CBPs are green, rationally use resources, and lead to a reduction in environmental pollution compared to alternative materials. However, incorporating high transparency, water resistance, mechanical robustness, wet-adhesion, ionic conductivity and recyclability into CBP remains a challenge. In this paper, novel CBPs with supramolecular covalent networks are fabricated by introducing polymerizable hydrophobic deep eutectic solvents (HDES) into ethylcellulose (EC) networks through in situ plasticization followed by a rapid photopolymerization process. The excellent molecular interfacial compatibility enables EC to be loaded with a high content of poly(HDES), while allowing high transparency (more than 90 %) of the prepared CBPs. Multiple intermolecular interactions provide CBPs with mechanical robustness, water resistance, and underwater adhesion, and CBPs can be readily recovered by the solvent in a closed loop. Moreover, CBPs possess inherent ionic conductivities, and using them as green substrates, personalized electroluminescent devices can be successfully constructed. The method proposed in this paper provides a new strategy for the preparation of multifunctional CBPs, which will greatly enrich their applications in self-adhesive materials, green flexible electronics and other package materials.

Topics & Concepts

Materials scienceAdhesiveHydroxypropyl celluloseCelluloseNanotechnologyDeep eutectic solventEutectic systemChemical engineeringPolymerComposite materialLayer (electronics)AlloyEngineeringAdvanced Sensor and Energy Harvesting Materialsbiodegradable polymer synthesis and propertiesAdvanced Cellulose Research Studies
Green, recyclable, mechanically robust, wet-adhesive and ionically conductive cellulose-based bioplastics enabled by supramolecular covalent hydrophobic eutectic networks | Litcius