机构地区:[1]Institute for Clean Energy and Advanced Materials,School of Materials and Energy,Southwest University,Chongqing 400715,People’s Republic of China [2]Sino‑Singapore Joint Laboratory of Materials and Technologies for Proactive Health Monitoring,School of Materials and Energy,Southwest University,Chongqing 400715,People’s Republic of China [3]Experimental Center for Virtual Simulation of Sports and Health,Southwest University,Chongqing 400715,People’s Republic of China [4]State Key Laboratory of Advanced Technology for Materials Synthesis and Processing,Wuhan University Technology,Wuhan 430070,People’s Republic of China [5]Hubei Longzhong Lab,Xiangyang 441000,People’s Republic of China [6]Key Laboratory of Laser Technology and Optoelectronic Functional Materials of Hainan Province,College of Chemistry and Chemical Engineering,Hainan Normal University,Haikou 571158,People’s Republic of China [7]Singapore Institute of Manufacturing Technology,Singapore 138669,Singapore
出 处:《Advanced Fiber Materials》2023年第5期1699-1711,共13页先进纤维材料(英文)
基 金:supported by the National Natural Science Foundation of China(Grant No.22272130);the Innovation Research 2035 Pilot Plan of Southwest University(Grant No.SWU-XDPY22014);the specific research fund of Innovation Platform for Academicians of Hainan Province(Grant No.YSPTZX202126);the Innovation Platform for Academicians of Hainan Province.
摘 要:Electrospun materials have attracted considerable attention in microbial fuel cells(MFC)owing to their porous structures,which facilitate the growth of electro-active biofilms(EABs).However,the impact of fiber diameter-controlled porous architectures on EAB growth and MFC performance has not been extensively studied.Herein,a highly conductive polypyrrole-modified electrospun polyacrylonitrile(PAN)mat was prepared as an electrode material for Shewanella putrefaciens CN32-based MFCs.The dominant pore size of the corresponding mat increases from 1 to around 20μm as the fiber diameter increases from 720 to 3770 nm.This variation affects the adhesion and growth behaviors of electrochemically active bacteria on the mat-based electrodes.The electrodes with poresranging from 2 to 10μm allow bacterial penetration into the interior,leading to significant biofilm loading and effective bioelectrocatalysis.However,the tight lamination of the electrospun fibers restricts bacterial growth in the deep interior space.We developed a friction-induced triboelectric expanding approach to rendering the mats with layered structures to overcome this limitation.The inter-layer spaces of the expanded conductive mat can facilitate bacterial loading from both sides of each layer and serve as channels to accelerate the catalysis of organic substances.Therefore,the expanded conductive mat with appropriate pore sizes delivers superior bioelectrocatalytic performance in MFCs and dye degradation.Based on the findings,a mechanism for the porous structure-controlled EAB formation and bioelectrocatalytic performance was proposed.This work may provide helpful guidance and insights for designing microfiber-based electrodes for microbial fuel cells.
关 键 词:Electrospun mat Porous structure BIOELECTROCATALYSIS Microbial fuel cells POLYPYRROLE
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