Artificial Mn4-oxido complexes mimic the oxygen-evolving center in photosynthesis 被引量：3

Artificial Mn_4-oxido complexes mimic the oxygen-evolving center in photosynthesis

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摘要 The understanding of the structure-function relationship of the oxygen-evolving center(OEC), a Mn_4 Cacluster, in photosystem II is impeded mainly due to the complexity of the protein environment and lack of rational chemical models as a reference. In this study, two novel Mn_4-oxido complexes have been synthesized and characterized, in which the peripheral ligands of the [Mn_4~Ⅲ] core are provided by eight μ_2-carboxylate groups and two neutral terminal ligands(pyridine or isoquinoline). This type of peripheral ligation is very similar to the Mn_4Ca-oxide model complexes recently reported to mimic the OEC. The new Mn_4-oxide complex can catalyze the oxygen-evolving reaction in the presence of Bu^tOOH as an oxidant. The structure and redox properties comparison of the Mn_4-oxido and Mn_4Ca-oxido complexes provide important clues to understanding the functional role of Ca in the OEC in natural photosynthesis, and develop more efficient artificial catalysts for the water-splitting reaction in the future. The understanding of the structure-function relationship of the oxygen-evolving center （OEC）, a MnaCacluster, in photosystem I1 is impeded mainly due to the complexity of the protein environment and lack of rational chemical models as a reference. In this study, two novel Mna-oxido complexes have been synthesized and characterized, in which the peripheral ligands of the [Mn4] core are provided by eight μ2-carboxylate groups and two neutral terminal ligands （pyridine or isoquinoline）. This type of peripheral ligation is very similar to the Mn4Ca-oxide model complexes recently reported to mimic the OEC. The new Mn4-0xide complex can catalyze the oxygen-evoNing reaction in the presence of But00H as an oxidant. The structure and redox properties comparison of the Mn4-0xido and Mn4Ca-oxido complexes provide important clues to understanding the functional role of Ca in the OEC in natural photosynthesis, and develop more efficient artificial catalysts for the water-splitting reaction in the future.

作者 Wenyan Chang Changhui Chen Hongxing Dong Chunxi Zhang

机构地区 Polymer Materials Research Center Laboratory of Photochemistry University of Chinese Academy of Sciences

出处《Science Bulletin》 SCIE EI CAS CSCD 2017年第9期665-668,共4页 科学通报（英文版）

基金 supported by the National Natural Science Foundation of China (20973186,31070216,21076049,and 91427303) the Strategic Priority Research Program of the Chinese Academy of Sciences (XDB17030600)

关键词 Natural photosynthesis Artificial photosynthesis Oxygen-evolving reaction Mn4Ca-cluster Mn4-oxido complex Natural photosynthesis Artificial photosynthesis Oxygen-evolving reaction Mn4Ca-cluster Mn4-oxido complex

分类号 O641.4 [理学—物理化学] O644.1 [理学—物理化学]

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参考文献3

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3Yuangang Qu,Shuai Zhang,Yuji Lian,Tingyun Kuang.Function of terahertz spectra in monitoring the decomposing process of biological macromolecules and in investigating the causes of photoinhibition[J].Science China(Life Sciences),2017,60(3):307-312.
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同被引文献6

1Chunxi Zhang,Jie Pan,Liangbi Li,Tingyun Kuang.New structure model of oxygen-evolving center and mechanism for oxygen evolution in photosynthesis[J].Chinese Science Bulletin,1999,44(24):2209-2215. 被引量：6
2王鸾,张纯喜,赵井泉.Synthesis, Structure and Catalytic Activity of a Manganese(Ⅲ) Complex Based on 2-(2-Hydroxyphenyl)-5,6-dichlorobenzimidazole Ligands[J].Chinese Journal of Structural Chemistry,2014,33(10):1479-1487. 被引量：2
3ZHANG ChunXi.The first artificial Mn_4Ca-cluster mimicking the oxygen-evolving center in photosystem Ⅱ[J].Science China(Life Sciences),2015,58(8):816-817. 被引量：6
4张纯喜.从自然光合作用到人工光合作用[J].中国科学：化学,2016,46(10):1101-1109. 被引量：4
5张杭,王磊,徐航勋.用于光催化全解水的二维高分子材料研究进展[J].功能高分子学报,2019,32(2):140-154. 被引量：10
6Tingyun Kuang.A breakthrough of artificial photosynthesis[J].National Science Review,2016,3(1):2-3. 被引量：4

引证文献3

1赵国清,李彦洗,陈长辉,张纯喜.Syntheses, Crystal Structures and Catalytic Activities of Two Novel Mn_2Dy_2O_2 Complexes[J].Chinese Journal of Structural Chemistry,2019,38(1):109-116.
2张颖,王磊,徐航勋.高分子光催化材料表面活性位点及其反应机理探究[J].高分子学报,2020,51(11):1201-1213.
3张纯喜.光合作用放氧反应[J].自然杂志,2021,43(3):199-208.

1Mariano Martin.Artificial versus Natural Reuse of CO2 for DME Production：Are We Any Closer？[J].Engineering,2017,3(2):166-170.

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