石墨烯
微纤维
纤维素
分子动力学
材料科学
化学工程
水溶液
吸附
氢键
两亲性
疏水效应
纳米技术
化学
有机化学
分子
复合材料
计算化学
聚合物
共聚物
工程类
作者
Linghan Kong,Rasha Alqus,Chin W. Yong,Ilian T. Todorov,Stephen J. Eichhorn,Richard A. Bryce
标识
DOI:10.1016/j.jmgm.2022.108336
摘要
Graphene-cellulose interactions have considerable potential in the development of new materials. In previous computational work (Biomacromolecules 2016, 16, 1771), we predicted that the model 100 hydrophobic surface of cellulose interacted favourably with pristine graphene in aqueous solution molecular dynamics simulations; conversely, a model of the hydrophilic 010 surface of cellulose exhibited progressive rearrangement to present a more hydrophobic face with the graphene, with weakened hydrogen bonds between cellulose chains and partial permeation of water. Here, we extend this work by simulating the interaction in aqueous solution of the amphiphilic 110 surface of a cellulose Iβ microfibril model, comprising 36 chains of 40 glucosyl residues, with an infinite sheet of pristine graphene. This face of the microfibril is of intermediate hydrophilicity and progressively associates with graphene over replicate simulations. As cellulose chains adhere to the graphene surface, forming interactions via its CH and OH groups, we observe a degree of local and global untwisting of the microfibril. Complementary rippling of the graphene surface is also observed, as it adapts to interaction with the microfibril. This adsorption process is accompanied by increased exclusion of water between cellulose and graphene although some water localises between chains at the immediate interface. The predicted propensity of a cellulose microfibril to adsorb spontaneously on the graphene surface, with mutual structural accommodation, highlights the amphiphilic nature of cellulose and the types of interactions that can be harnessed to design new graphene-carbohydrate biopolymer materials.
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