CAJ | 학술논문

近年来，随着太阳能被引入微生物燃料电池领域，微生物电化学-光电化学协同产电、产燃料或净化环境的技术成为研究热点。太阳能转化的常用媒介是金属氧化物，探究其与微生物间的相互作用对认清协同机理、提高体系效率等方面有重大意义。综述了不同类型的金属氧化物-微生物相互作用的研究工作，包括微生物-金属氧化物间物理吸附作用、微生物对金属氧化物的矿化和风化作用、微生物-金属氧化物协同产电产燃料系统、金属氧化物光催化杀菌以及光电-微生物电化学协同治理有机污染物或重金属污染，提出了更高效的微生物电化学-光电化学体系的构建方法，为微生物-光催化材料协同体系的实际应用提供帮助。
근년래，수착태양능피인입미생물연료전지영역，미생물전화학-광전화학협동산전、산연료혹정화배경적기술성위연구열점。태양능전화적상용매개시금속양화물，탐구기여미생물간적상호작용대인청협동궤리、제고체계효솔등방면유중대의의。종술료불동류형적금속양화물-미생물상호작용적연구공작，포괄미생물-금속양화물간물리흡부작용、미생물대금속양화물적광화화풍화작용、미생물-금속양화물협동산전산연료계통、금속양화물광최화살균이급광전-미생물전화학협동치리유궤오염물혹중금속오염，제출료경고효적미생물전화학-광전화학체계적구건방법，위미생물-광최화재료협동체계적실제응용제공방조。
Since solar power was introduced into the microbial fuel cell (MFC) field, there is great interest in microbial electrochemical-photoelectrochemical synergetic systems used for electrogenesis, fuel production or environmental cleaning. Metal oxide is a common medium in solar power conversion. Research on interaction between microorganism and metal oxide is necessary to understand synergy mechanism or enhance efficiency. In this paper, various interactions between microorganism and metal oxide are summarized according to physical absorption, microbial weathering, microbial mining, photocatalytic sterilization and microbe-metal oxide synergistic effects, providing a reference for the construction of efficient microbial electrochemical-photoelectrochemical synergetic systems.