Ru(II) and Rh(III) porphyrin complexes of primary phosphine-substituted porphyrins
Ru(II) and Rh(III) porphyrin complexes of primary phosphine-substituted porphyrins
Primary alkynyl phosphine porphyrins were prepared by AlHCl2 reduction of the corresponding alkynyl phosphonates. Dephosphorylation of the alkyne proved to be a major side reaction. Using LiAlH4 as reducing agent, the alkyne was found to be partially reduced to give the trans-alkenyl phosphine selectively. The primary phosphines coordinate to both ruthenium(II) and rhodium(III) porphyrins and readily form bis-phosphine complexes. The 1H and 31P NMR spectra for the ruthenium complexes show a pattern characteristic of an [AX2]2 spin system with an unusually large 2JPP coupling constant of 620.6 Hz. The IR spectrum of the complex (PAPH2)Ru(CO)(porphyrin)(PAPH2=phenylacetylenephosphine) indicates weak sigma-donor properties of the ligand. In contrast to the corresponding tertiary phosphine complexes, the bis-phosphine complexes with both ruthenium(II) and rhodium(III) porphyrins are more stable than the mono-phosphine complexes, as judged by NMR spectroscopy, and they can also be detected in the gas phase by LDI-TOF MS. In all cases the complexes could not be isolated and they degrade within hours at ambient temperatures when kept in solution. These compounds may therefore not be suitable for the construction of larger multiporphyrin systems, but their accessibility makes it possible to study their coordination behaviour with other transition metals.
1066-1072
Stulz, Eugen
9a6c04cf-32ca-442b-9281-bbf3d23c622d
Maue, Michael
13d5359d-0b30-4815-a1cd-8170e02e7a96
Scott, Sonya M.
3b702a61-a831-421a-b3a1-d146c7a71389
Mann, Brian E.
91490765-e58d-414a-8ea5-089267d49896
Sanders, Jeremy K.M.
a676d635-3196-437a-b894-a2bc5f857ae2
2004
Stulz, Eugen
9a6c04cf-32ca-442b-9281-bbf3d23c622d
Maue, Michael
13d5359d-0b30-4815-a1cd-8170e02e7a96
Scott, Sonya M.
3b702a61-a831-421a-b3a1-d146c7a71389
Mann, Brian E.
91490765-e58d-414a-8ea5-089267d49896
Sanders, Jeremy K.M.
a676d635-3196-437a-b894-a2bc5f857ae2
Stulz, Eugen, Maue, Michael, Scott, Sonya M., Mann, Brian E. and Sanders, Jeremy K.M.
(2004)
Ru(II) and Rh(III) porphyrin complexes of primary phosphine-substituted porphyrins.
New Journal of Chemistry, 28, .
(doi:10.1039/b402083a).
Abstract
Primary alkynyl phosphine porphyrins were prepared by AlHCl2 reduction of the corresponding alkynyl phosphonates. Dephosphorylation of the alkyne proved to be a major side reaction. Using LiAlH4 as reducing agent, the alkyne was found to be partially reduced to give the trans-alkenyl phosphine selectively. The primary phosphines coordinate to both ruthenium(II) and rhodium(III) porphyrins and readily form bis-phosphine complexes. The 1H and 31P NMR spectra for the ruthenium complexes show a pattern characteristic of an [AX2]2 spin system with an unusually large 2JPP coupling constant of 620.6 Hz. The IR spectrum of the complex (PAPH2)Ru(CO)(porphyrin)(PAPH2=phenylacetylenephosphine) indicates weak sigma-donor properties of the ligand. In contrast to the corresponding tertiary phosphine complexes, the bis-phosphine complexes with both ruthenium(II) and rhodium(III) porphyrins are more stable than the mono-phosphine complexes, as judged by NMR spectroscopy, and they can also be detected in the gas phase by LDI-TOF MS. In all cases the complexes could not be isolated and they degrade within hours at ambient temperatures when kept in solution. These compounds may therefore not be suitable for the construction of larger multiporphyrin systems, but their accessibility makes it possible to study their coordination behaviour with other transition metals.
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Published date: 2004
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Local EPrints ID: 41346
URI: http://eprints.soton.ac.uk/id/eprint/41346
ISSN: 1144-0546
PURE UUID: c563bcf4-6d8d-4b56-b70e-d94649187019
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Date deposited: 22 Aug 2006
Last modified: 16 Mar 2024 03:51
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Author:
Michael Maue
Author:
Sonya M. Scott
Author:
Brian E. Mann
Author:
Jeremy K.M. Sanders
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