光合作用中心的人工模拟
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- 英文论文题名:Artificial Photosynthetic Systems for Chemical Transformation
- 论文作者:吴骊珠
- 英文论文作者:Li-Zhu Wu ; Key Laboratory of Photochemical Conversion and Optoelectronic Materials ; Technical Institute of Physics and Chemistry ; the Chinese Academy of Sciences
- 年:2016
- 作者机构:中国科学院理化技术研究所;
- 论文关键词:光合作用 ; 人工模拟 ; 人工光合成
- 会议召开时间:2016-07-01
- 会议录名称:中国化学会第30届学术年会摘要集-第二十四分会:超分子组装与软物质材料
- 语种:中文
- 分类号:O644.1
- 学会代码:ZGHY
- 会议名称:中国化学会第30届学术年会-第二十四分会 ; 超分子组装与软物质材料
- 会议地点:中国辽宁大连
- 主办单位:中国化学会
- 学会名称:中国化学会
- 页数:1
- 文件大小:105k
- 原文格式:D
- 会议级别:全国
摘要
光合作用是绿色植物(包括海藻)利用太阳光将二氧化碳和水合成有机物并释放氧气的过程,是地球上最大规模的能量和物质转换基础。光合作用起始于光捕获体系中叶绿素天然分子对光子的吸收,光合系统II利用吸收光子产生的空穴将水裂解为氧气,生成的电子和质子被传递到光合系统I,受光激发的光合系统I再将质子、电子和二氧化碳还原为葡萄糖;某些光合细菌的光合系统I可直接将光合系统II传递来的电子和质子还原放出氢气。我们模拟植物光合作用中心的工作原理,开展了多个光合作用中心体系构建和催化机理的工作,利用自组装的原理模拟还原了自然界光合作用中心的工作环境;构筑了高效、稳定、廉价的人工光合成催化的新体系~([1-3])。
Nature long ago figured out how to use photosynthetic complex to capture sunlight and then to store its energy in a chemical form. To mimic the functionality of the active sites, we have devoted ourselves to artificial photosynthetic systems to understand the mechanism of stepwise electron transfer and proton reduction in the active site of artifical photosynthetic systems, and to develop artificial photocatalysts that are earth-abundant and capable of simulating the functionality of natural metalloenzymes with high efficiency and stability.
Nature long ago figured out how to use photosynthetic complex to capture sunlight and then to store its energy in a chemical form. To mimic the functionality of the active sites, we have devoted ourselves to artificial photosynthetic systems to understand the mechanism of stepwise electron transfer and proton reduction in the active site of artifical photosynthetic systems, and to develop artificial photocatalysts that are earth-abundant and capable of simulating the functionality of natural metalloenzymes with high efficiency and stability.
引文
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[2]Ye,C.;Li,J.-X.;Li,Z.-J.;Li,X.-B.;Fan,X.-B.;Zhang,L.-P.;Chen,B.;Tung,C.-H.;Wu,L.-Z.ACS Catal.2015,5:6973;Li,J.-X.;Li,Z.-J.;Ye,C.;Li,X.-B.;Zhan,F.;Fan,X.-B.;Li,J.;Chen,B.;Tao,Y.;Tung C.-H.;Wu,L.-Z.Catal.Sci.Technol.2016,6:672;Yang,B.;Jiang,X.;Guo,Q.;Lei,T.;Zhang,L.-P.;Chen,B.;Tung,C.-H.;Wu,L.-Z.Angew.Chem.Int.Ed.2016,DOI:10.1002/anie.201601653.
[3]Liu,B.;Li,X.-B.;Gao,Y.-J.;Li,Z.-J.;Meng,Q.-Y.;Tung,C.-H.;Wu,L.-Z.Energy Environ.Sci.2015,8:1443;Li,X.-B.;Liu,B.;Wen,M.;Gao,Y.-J.;Wu,H.-L.;Huang,M.-Y.;Li,Z.-J.;Chen,B.;Tung,C.-H.;Wu,L.-Z.Adv.Sci.2016,3:1500282;Li,J.;Gao,X.;Liu,B.;Feng,Q.;Li,X.-B.;Huang,M.-Y.;Liu,Z.;Zhang,J.;Tung,C.-H.;Wu,L.-Z.J.Am.Chem.Soc.2016,138:3954.