Nanocellulose and its derivative materials for energy and environmental applications

The application of biomass-derived renewable materials has generated great interest in recent research works. Among many such biopolymers, nanocellulose has become the leading topic in the sphere of sustainable material owing to the outstanding mechanical, chemical and thermal properties along with...

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Veröffentlicht in:	Journal of materials science 2022-04, Vol.57 (13), p.6835-6880
Hauptverfasser:	Peter, Sherin, Lyczko, Nathalie, Gopakumar, Deepu, Maria, Hanna J., Nzihou, Ange, Thomas, Sabu
Format:	Artikel
Sprache:	eng
Schlagworte:	Batteries Biodiesel fuels Biofuels Biomass Biomass energy Biopolymers Biosensors Cellulose Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Composite materials Crystallography and Scattering Methods Energy Forecasts and trends Fuel cells Functional materials Heavy metals Lithium-ion batteries Materials Science Mechanical properties Photovoltaic cells Polymer Sciences Rechargeable batteries Renewable resources Review Shielding Solar cells Solid Mechanics Surface charge Sustainability Sustainable materials Thermal decomposition Thermal properties Thermodynamic properties Toxicity Trends
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creator	Peter, Sherin Lyczko, Nathalie Gopakumar, Deepu Maria, Hanna J. Nzihou, Ange Thomas, Sabu
description	The application of biomass-derived renewable materials has generated great interest in recent research works. Among many such biopolymers, nanocellulose has become the leading topic in the sphere of sustainable material owing to the outstanding mechanical, chemical and thermal properties along with non-toxicity, surface functionality, ease of modification and sustainability. Nanocellulose is often considered to be a second-generation renewable resource and a better replacement for conventional petroleum-based products with or without any modifications. Even though some reviews have reported on some of the applications of nanocellulose, so far there is no comprehensive report gathering the extraction, properties, functionalization towards energy and environmental applications. This review aims to present the use of nanocellulose based materials for energy and environmental challenges. Important characteristics such as crystallinity, hydrophilicity, thermal decomposition and surface charge are described as a function of the targeted applications. In the latter part of this review, we have looked into the recent studies in the area of applications such as air pollution, heavy metal sorption, dye adsorption, biosensors, EMI shielding, fuel cell, solar cell, lithium-ion batteries and biofuels etc. However, a green, sustainable and scalable nanocellulose extraction is yet to be fulfilled. In our view, the bacterial nanocellulose based approach can address all these issues with the added advantage of producing a very high purity of nanocellulose. Hence this review is intended to provide new insights into the field of eco-friendly functional materials with included in-depth perspectives about nanocellulose and its future based on the current research trends. Graphical Abstract
doi_str_mv	10.1007/s10853-022-07070-6
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subjects	Batteries Biodiesel fuels Biofuels Biomass Biomass energy Biopolymers Biosensors Cellulose Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Composite materials Crystallography and Scattering Methods Energy Forecasts and trends Fuel cells Functional materials Heavy metals Lithium-ion batteries Materials Science Mechanical properties Photovoltaic cells Polymer Sciences Rechargeable batteries Renewable resources Review Shielding Solar cells Solid Mechanics Surface charge Sustainability Sustainable materials Thermal decomposition Thermal properties Thermodynamic properties Toxicity Trends
title	Nanocellulose and its derivative materials for energy and environmental applications
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