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Nickel carbonyl [Ni(CO)4] and iron carbonyl [Fe(CO)5]: molecular structures in the solid state

Cite this: Organometallics 1993, 12, 4, 1481–1483
Publication Date (Print):April 1, 1993
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    82. Wolfgang Imhof, Helmar Görls, Kathi Halbauer. Tris( tert -butyl isocyanide-κ C )carbonylnickel(0). Acta Crystallographica Section E Structure Reports Online 2008, 64 (8) , m1000-m1000.
    83. Sylvie Samson, G. Richard Stephenson, James P. Stambuli. Pentacarbonyliron. 2008
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    87. F. W. Averill, G. S. Painter. Convergence properties of the Harris density functional and the self-consistent atom fragment approximation. Physical Review B 2006, 73 (23)
    88. Mayuko Ushiro, Kanae Uno, Takashi Fujikawa, Yoshinori Sato, Kazuyuki Tohji, Fumio Watari, Wang-Jae Chun, Yuichiro Koike, Kiyotaka Asakura. X-ray absorption fine structure (XAFS) analyses of Ni species trapped in graphene sheet of carbon nanofibers. Physical Review B 2006, 73 (14)
    89. Alonzo Martinez, Michael D. Morse. Infrared diode laser spectroscopy of jet-cooled NiCO, Ni(CO)3(C13O), and Ni(CO)3(CO18). The Journal of Chemical Physics 2006, 124 (12)
    90. Chun-Liang Lai, Wen-Hsin Guo, Ming-Tsung Lee, Ching-Han Hu. Ligand properties of N-heterocyclic and Bertrand carbenes: A density functional study. Journal of Organometallic Chemistry 2005, 690 (24-25) , 5867-5875.
    91. Hans-Jörg Himmel, Laurent Manceron. Ni(N2)4 revisited: an analysis of the Ni–N2 bonding properties of this benchmark system on the basis of UV/Vis, IR and Raman spectroscopy. Dalton Transactions 2005, 144 (15) , 2615.
    92. Mayuko Ushiro, Kiyotaka Asakura, Kenryo Ohminami, Shin-ichi Nagamatsu, Takashi Fujikawa. Structure and Bonding of Trace Ni Catalyst in Carbon Nanotube Studied by Ni K-Edge XANES. e-Journal of Surface Science and Nanotechnology 2005, 3 , 427-432.
    93. Taewoo Lee, Frank Benesch, Yan Jiang, Christoph G. Rose-Petruck. Structure of solvated Fe(CO)5: XANES and EXAFS measurements using ultrafast laser plasma and conventional X-ray sources. Chemical Physics 2004, 299 (2-3) , 233-245.
    94. Eduard Bernhardt, Maik Finze, Helge Willner, Christian W. Lehmann, Friedhelm Aubke. [Co(CO) 5 ][(CF 3 ) 3 BF]: ein stabiles Salz eines homoleptischen trigonal‐bipyramidalen Metallcarbonyl‐Kations. Angewandte Chemie 2003, 115 (18) , 2123-2125.
    95. Eduard Bernhardt, Maik Finze, Helge Willner, Christian W. Lehmann, Friedhelm Aubke. [Co(CO) 5 ][(CF 3 ) 3 BF]: A Stable Salt of a Homoleptic Trigonal‐Bipyramidal Metal–Carbonyl Cation. Angewandte Chemie International Edition 2003, 42 (18) , 2077-2079.
    96. F. Meyer, H. Kozlowski. Nickel. 2003, 247-554.
    97. STEPHAN SCHULZ. Group 13/15 Organometallic Compounds—Synthesis, Structure, Reactivity and Potential Applications. 2003, 225-317.
    98. Bryan H. Kim, Carl R.F. Lund. Issues involved in using MCSCF to investigate catalytic sites involving transition metals. Journal of Molecular Catalysis A: Chemical 2002, 188 (1-2) , 173-187.
    99. Gilles Boni, Olivier Blacque, Philippe Sauvageot, Nicolas Poujaud, Claude Moı̈se, Marek M Kubicki. Tantalocenehydridephosphorus chemistry.. Polyhedron 2002, 21 (4) , 371-379.
    100. Stephan Schulz. Synthesis, Structure and Reactivity of Group 13/15 Compounds Containing the Heavier Elements of Group 15, Sb and Bi. 2002, 117-166.
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