Delivering carbide ligands to sulfide-rich clusters

被引:28
|
作者
Reinholdt, Anders [1 ]
Herbst, Konrad [2 ]
Bendix, Jesper [1 ]
机构
[1] Univ Copenhagen, Dept Chem, Univ Pk 5, DK-2100 Copenhagen, Denmark
[2] Haldor Topsoe Res Labs, Haldor Topsoes Alle 1, DK-2800 Lyngby, Denmark
来源
CHEMICAL COMMUNICATIONS | 2016年 / 52卷 / 10期
关键词
OLEFIN METATHESIS REACTIONS; NITROGENASE FEMO COFACTOR; INTERSTITIAL CARBIDE; CRYSTAL-STRUCTURES; BRIDGED COMPLEXES; CARBON-MONOXIDE; ATOM-TRANSFER; RUTHENIUM; IRON; CUBANE;
D O I
10.1039/c5cc08918b
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
The propensity of the terminal ruthenium carbide Ru(C)Cl-2(PCy3)(2)(RuC) to form carbide bridges to electron-rich transition metals enables synthetic routes to metal clusters with coexisting carbide and sulfide ligands. Electrochemical experiments show the RuRC ligand to exert a relatively large electron-withdrawing effect compared with PPh3, effectively shifting redox potentials.
引用
收藏
页码:2015 / 2018
页数:4
相关论文
共 50 条
  • [31] Iron and arsenic-rich nanoprecipitates associated with clay minerals in sulfide-rich waste dumps
    Valente, T.
    Gomes, P.
    Sequeira Braga, M. A.
    Dionisio, A.
    Pamplona, J.
    Grande, J. A.
    CATENA, 2015, 131 : 1 - 13
  • [32] Genetic, biochemical, and physiological adaptation in fish inhabiting sulfide-rich environments
    Barts, N.
    Henpita, C.
    Greenway, R.
    Arndt, S.
    Shaw, J.
    Tobler, M.
    INTEGRATIVE AND COMPARATIVE BIOLOGY, 2019, 59 : E12 - E12
  • [33] Effect of autotrophic denitrification on nitrate migration in sulfide-rich marine sediments
    Zhen Zhang
    Irene M. C. Lo
    Guanyu Zheng
    Kok Sin Woon
    Pinhua Rao
    Journal of Soils and Sediments, 2015, 15 : 1019 - 1028
  • [34] MOSSBAUER SPECTRAL STUDIES OF THE DIAGENESIS OF IRON IN A SULFIDE-RICH SEDIMENT CORE
    MANNING, PG
    WILLIAMS, JDH
    CHARLTON, MN
    ASH, LA
    BIRCHALL, T
    NATURE, 1979, 280 (5718) : 134 - 136
  • [35] Adaptation of cyanobacteria to the sulfide-rich microenvironment of black band disease of coral
    Myers, Jamie L.
    Richardson, Laurie L.
    FEMS MICROBIOLOGY ECOLOGY, 2009, 67 (02) : 242 - 251
  • [36] Sulfide-rich metallic impact melts from chondritic parent bodies
    Schrader, Devin L.
    Lauretta, Dante S.
    Connolly, Harold C., Jr.
    Goreva, Yulia S.
    Hill, Dolores H.
    Domanik, Ken J.
    Berger, Eve L.
    Yang, Hexiong
    Downs, Robert T.
    METEORITICS & PLANETARY SCIENCE, 2010, 45 (05) : 743 - 758
  • [37] Metabolic Physiology of Extremophile Fish Inhabiting Hydrogen Sulfide-Rich Environments
    Barts, N.
    Nieves, N.
    Tobler, M.
    INTEGRATIVE AND COMPARATIVE BIOLOGY, 2018, 58 : E12 - E12
  • [38] Mobility and attenuation of arsenic in sulfide-rich mining wastes from the Czech Republic
    Drahota, Petr
    Knappova, Magdalena
    Kindlova, Helena
    Culka, Adam
    Majzlan, Juraj
    Mihaljevic, Martin
    Rohovec, Jan
    Veselovsky, Frantisek
    Fridrichova, Michaela
    Jehlicka, Jan
    SCIENCE OF THE TOTAL ENVIRONMENT, 2016, 557 : 192 - 203
  • [39] Nitrate reduction coupled with pyrite oxidation in the surface sediments of a sulfide-rich ecosystem
    Hayakawa, Atsushi
    Hatakeyama, Mizuho
    Asano, Ryoki
    Ishikawa, Yuichi
    Hidaka, Shin
    JOURNAL OF GEOPHYSICAL RESEARCH-BIOGEOSCIENCES, 2013, 118 (02) : 639 - 649
  • [40] Effect of the chemical oxidation demand to sulfide ratio on sulfide oxidation in microbial fuel cells treating sulfide-rich wastewater
    Zhang, Lehua
    Mao, Yanping
    Ma, Jingxing
    Li, Dongmei
    Shi, Haifeng
    Liu, Yongdi
    Cai, Lankun
    ENVIRONMENTAL TECHNOLOGY, 2013, 34 (02) : 269 - 274
12345