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Mechanism of ethanol/water reverse separation through a functional graphene membrane:a molecular simulation investigation

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Frontiers of Chemical Science and Engineering 2023年第3期17卷 347-357页

作者： Quan Liu Xian Wang Yanan Guo Gongping Liu Kai-Ge Zhou School of Chemical Engineering Analytical and Testing CenterAnhui University of Science and TechnologyHuainan 232001China State Key Laboratory of Materials-Oriented Chemical Engineering College of Chemical EngineeringNanjing Tech UniversityNanjing 211816China Haihe Laboratory of Sustainable Chemical Transformations Tianjin 300192China

Reverse-selective membranes have attracted considerable interest for bioethanol production.However,to date,the reverse-separation performance of ethanol/water is poor and the separation mechanism is unclear.graphene-based membranes with tunable apertures and functional groups have shown substantial potential for use in molecular separation.Using molecular dynamics simulations,for the first time,we reveal twoway selectivity in ethanol/water separation through functional graphene membranes.Pristine graphene(PG)exhibits reverse-selective behavior with higher ethanol fluxes than water,resulting from the preferential adsorption for ethanol.Color flow mappings show that this ethanol-permselective process is initiated by the presence of ethanol-enriched and water-barren pores;this has not been reported in previous studies.In contrast,water molecules are preferred for hydroxylated graphene membranes because of the synergistic effects of molecular sieving and functional-group attraction.A simulation of the operando condition shows that the PG membrane with an aperture size of 3.8Åachieves good separation performance,with an ethanol/water separation factor of 34 and a flux value of 69.3 kg∙m‒2∙h‒1∙bar‒1.This study provides new insights into the reverse-selective mechanism of porous graphene membranes and a new avenue for efficient biofuel production.

关键词： reverse separation graphene membrane ethanol/water separation molecular simulation

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Facilely prepared layer-by-layer graphene membrane-based pressure sensor with high sensitivity and stability for smart wearable devices

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Journal of Materials Science & Technology 2020年第10期42卷 241-247页

作者： Tao Liu Caizhen Zhu Wei Wu Kai-Ning Liao Xianjing Gong Qijun Sun Robert K.Y.Li Department of Materials Science and Engineering City University of Hong KongTat Chee AvenueKowloonHong KongChina Institute of Low-dimensional Materials Genome Initiative College of Chemistry and Environmental EngineeringShenzhen UniversityShenzhen518060China National Engineering Research Center of Novel Equipment for Polymer Processing Key Laboratory of Polymer Processing Engineering of Ministry of EducationSchool of Mechanical and Automotive EngineeringSouth China University of TechnologyGuangzhou510640China State Key Laboratory of Organic-Inorganic Composites College of Materials Science and EngineeringBeijing University of Chemical TechnologyBeijing100029China

With the prosperous development of artificial intelligence,medical diagnosis and electronic skins,wearable electronic devices have drawn much attention in our daily life.Flexible pressure sensors based on carbon materials with ultrahigh sensitivity,especially in a large pressure range regime are highly required in wearable applications.In this work,graphene membrane with a layer-by-layer structure has been successfully fabricated via a facile self-assembly and air-drying(SAAD)method.In the SAAD process,air-drying the self-assembled graphene hydrogels contributes to the uniform and compact layer structure in the obtained membranes.Owing to the excellent mechanical and electrical properties of graphene,the pressure sensor constructed by several layers of membranes exhibits high sensitivity(52.36 kPa……-1)and repeatability(short response and recovery time)in the loading pressure range of 0–50 kPa.Compared with most reported graphene-related pressure sensors,our device shows better sensitivity and wider applied pressure range.What’s more,we demonstrate it shows desired results in wearable applications for pulse monitoring,breathing detection as well as different intense motion recording such as walk,run and squat.It’s hoped that the facilely prepared layer-by-layer graphene membrane-based pressure sensors will have more potential to be used for smart wearable devices in the future.

关键词： graphene membrane Self-assembly High sensitivity Wearable devices Human motions

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快速微波还原电化学衍生氧化石墨烯制备高结晶石墨烯膜

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Science China Materials 2023年第12期66卷 4733-4741页

作者：熊志远于沛梁庆华李丹 School of Light Industry and Engineering South China University of TechnologyGuangzhou 510614China Department of Chemical Engineering The University of MelbourneParkvilleVictoria 3010Australia Department of Materials Science and Engineering Monash UniversityClaytonVictoria 3800Australia Key Laboratory of Rare Earth Ganjiang Innovation AcademyChinese Academy of SciencesGanzhou 341000China

电化学氧化石墨,可用于大规模合成氧化石墨烯,是一种可持续且直接的方法.然而,关于电化学衍生氧化石墨烯(EGO)进一步还原的研究却很缺少.本文中,我们报道了EGO膜的快速微波还原过程.化学法合成的氧化石墨烯膜需要数分钟微波辐射才能被还... 详细信息

电化学氧化石墨,可用于大规模合成氧化石墨烯,是一种可持续且直接的方法.然而,关于电化学衍生氧化石墨烯(EGO)进一步还原的研究却很缺少.本文中,我们报道了EGO膜的快速微波还原过程.化学法合成的氧化石墨烯膜需要数分钟微波辐射才能被还原,但是我们制备的EGO膜经3秒微波辐射即可转化为高结晶石墨烯膜(HCGM),并且该过程无需对膜进行预处理或添加微波增敏剂.与以前报道的微波法制备的石墨烯相比,本文制备的HCGM具有大尺寸芳香区(约100 nm)、高碳/氧原子比(约33)和高电导率(约5×10^(4)S m^(−1)).EGO的高微波还原效率可以归因于其独特分子结构,EGO中丰富的芳香区可高效吸收微波,引发EGO膜实现瞬时体相加热.该研究加深了对氧化石墨烯微波还原机理的理解,并为HCGM的生产提供了一条便捷途径.

关键词： graphene oxide graphene membrane electrochemical oxidation high crystallinity microwave reduction

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