香草醛修饰的壳聚糖作为可持续储能的电极材料。

Vanillin decorated chitosan as electrode material for sustainable energy storage.

作者信息

Ilic Ivan K, Meurer Maren, Chaleawlert-Umpon Saowaluk, Antonietti Markus, Liedel Clemens

机构信息

Department of Colloid Chemistry, Max Planck Institute of Colloids and Interfaces, Research Campus Golm 14476 Potsdam Germany

National Nanotechnology Center, National Science and Technology Development Agency Thailand Science Park Pathumtani 12120 Thailand.

出版信息

RSC Adv. 2019 Feb 6;9(8):4591-4598. doi: 10.1039/c9ra00140a. eCollection 2019 Jan 30.

DOI:10.1039/c9ra00140a

PMID:35520200

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9060616/

Abstract

Energy storage materials made from bioresources are crucial to fulfil the need for truly sustainable energy storage. In this work, vanillin, being a lignin-derived molecule, is coupled to chitosan, a biobased polymer backbone, and used as a redox active electrode material. The structure of those electrodes is highly defined, leading to better product security than in lignin based electrodes, which have been presented as sustainable electrodes in the past. With over 60% of saccharide units in chitosan functionalised by vanillin, the concentration of redox functionalities in the copolymer is significantly higher than in lignin materials. Composites with carbon black require no further binders or additives to be used as electrode material and show reversible charge storage up to 80 mA h g (respective to the total electrode material) and good stability. Consequently, these electrodes are amongst the best performing electrodes made from regrown organic matter.

摘要

由生物资源制成的储能材料对于满足真正可持续储能的需求至关重要。在这项工作中，香草醛作为一种源自木质素的分子，与壳聚糖（一种生物基聚合物主链）偶联，并用作氧化还原活性电极材料。这些电极的结构高度明确，与过去被视为可持续电极的木质素基电极相比，产品安全性更高。壳聚糖中超过60%的糖单元被香草醛官能化，共聚物中氧化还原官能团的浓度明显高于木质素材料。与炭黑的复合材料用作电极材料时无需进一步添加粘合剂或添加剂，并且显示出高达80 mA h g（相对于总电极材料）的可逆电荷存储和良好的稳定性。因此，这些电极是由再生有机物制成的性能最佳的电极之一。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/eb67/9060616/d70049c460c1/c9ra00140a-s1.jpg

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香草醛修饰的壳聚糖作为可持续储能的电极材料。

Vanillin decorated chitosan as electrode material for sustainable energy storage.

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