Osmium- and ruthenium-antimony carbonyl clusters and rings
The reaction of the lightly stabilized cluster Os3(CO)11(NCCH3) with the hydrostibine SbPh2H afforded the four-membered ring Os3(H)(CO)11(μ-SbPh2). A similar reaction with the distibine Sb2Ph4 gave the analogue Os3(SbPh2)(CO)11(μ-SbPh2), which can be regarded as a metalloligand with the presence of...
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sg-ntu-dr.10356-658722023-02-28T23:36:11Z Osmium- and ruthenium-antimony carbonyl clusters and rings Li, Yingzhou Leong Weng Kee School of Physical and Mathematical Sciences DRNTU::Science::Chemistry The reaction of the lightly stabilized cluster Os3(CO)11(NCCH3) with the hydrostibine SbPh2H afforded the four-membered ring Os3(H)(CO)11(μ-SbPh2). A similar reaction with the distibine Sb2Ph4 gave the analogue Os3(SbPh2)(CO)11(μ-SbPh2), which can be regarded as a metalloligand with the presence of a lone pair on the terminal SbPh2 group. Reactions of the Sb2Ph4 with the M3(CO)10(NCCH3)2 (M = Ru or Os) afforded the clusters M3(CO)10(μ-SbPh2)2, which featured fluxional M–M bonds. These clusters undergo ligand substitution reactions with two electron donors L to form M3(CO)9(L)(μ-SbPh2)2 or M3(CO)8(L)2(μ-SbPh2)2, and oxidative addition reactions with halogens X2 (X = Cl, I) to afford five-membered rings, or with the halo- and hydrostibines SbPh2X (X =Cl, H) to afford the fused ring products M3(X)(CO)9(μ-SbPh2)3. Reaction of the halostibine SbPh2Cl with Os3(CO)11(NCCH3) or Os3(CO)10(NCCH3)2 afforded the four- or five-membered metalloheterocycles Os3(Cl)(CO)11(μ-SbPh2) or Os3(Cl)2(CO)10(μ-SbPh2)2, respectively. A raft-like, higher nuclearity cluster Os6(CO)20(μ-SbPh2)2 was also isolated from the first reaction. With SbPhCl2, the reaction of Os3(CO)11(NCCH3) afforded two isomers of Os3(Cl)2(CO)11(μ3-SbPh). The latter could lose an Os(CO)3(Cl)2 fragment with PMe3 to form a “closed stibinidene” Os2(CO)8(μ3-SbPh), which could be trapped with W(CO)5(thf). These reactions led to complex mixtures with the corresponding ruthenium precursors. A better approach was through either the carbonylate [HRu3(CO)11]-, which afforded Ru–Sb clusters under mild conditions, or ketyl radical initiation of Ru3(CO)12 which afforded a higher nuclearity cluster Ru6(CO)20(μ-SbPh2)2 in a moderate yield. DOCTOR OF PHILOSOPHY (SPMS) 2016-01-06T02:49:20Z 2016-01-06T02:49:20Z 2016 2016 Thesis https://hdl.handle.net/10356/65872 10.32657/10356/65872 en 258 p. application/pdf application/pdf |
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DRNTU::Science::Chemistry Li, Yingzhou Osmium- and ruthenium-antimony carbonyl clusters and rings |
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The reaction of the lightly stabilized cluster Os3(CO)11(NCCH3) with the hydrostibine SbPh2H afforded the four-membered ring Os3(H)(CO)11(μ-SbPh2). A similar reaction with the distibine Sb2Ph4 gave the analogue Os3(SbPh2)(CO)11(μ-SbPh2), which can be regarded as a metalloligand with the presence of a lone pair on the terminal SbPh2 group. Reactions of the Sb2Ph4 with the M3(CO)10(NCCH3)2 (M = Ru or Os) afforded the clusters M3(CO)10(μ-SbPh2)2, which featured fluxional M–M bonds. These clusters undergo ligand substitution reactions with two electron donors L to form M3(CO)9(L)(μ-SbPh2)2 or M3(CO)8(L)2(μ-SbPh2)2, and oxidative addition reactions with halogens X2 (X = Cl, I) to afford five-membered rings, or with the halo- and hydrostibines SbPh2X (X =Cl, H) to afford the fused ring products M3(X)(CO)9(μ-SbPh2)3. Reaction of the halostibine SbPh2Cl with Os3(CO)11(NCCH3) or Os3(CO)10(NCCH3)2 afforded the four- or five-membered metalloheterocycles Os3(Cl)(CO)11(μ-SbPh2) or Os3(Cl)2(CO)10(μ-SbPh2)2, respectively. A raft-like, higher nuclearity cluster Os6(CO)20(μ-SbPh2)2 was also isolated from the first reaction. With SbPhCl2, the reaction of Os3(CO)11(NCCH3) afforded two isomers of Os3(Cl)2(CO)11(μ3-SbPh). The latter could lose an Os(CO)3(Cl)2 fragment with PMe3 to form a “closed stibinidene” Os2(CO)8(μ3-SbPh), which could be trapped with W(CO)5(thf). These reactions led to complex mixtures with the corresponding ruthenium precursors. A better approach was through either the carbonylate [HRu3(CO)11]-, which afforded Ru–Sb clusters under mild conditions, or ketyl radical initiation of Ru3(CO)12 which afforded a higher nuclearity cluster Ru6(CO)20(μ-SbPh2)2 in a moderate yield. |
| author2 |
Leong Weng Kee |
| author_facet |
Leong Weng Kee Li, Yingzhou |
| format |
Theses and Dissertations |
| author |
Li, Yingzhou |
| author_sort |
Li, Yingzhou |
| title |
Osmium- and ruthenium-antimony carbonyl clusters and rings |
| title_short |
Osmium- and ruthenium-antimony carbonyl clusters and rings |
| title_full |
Osmium- and ruthenium-antimony carbonyl clusters and rings |
| title_fullStr |
Osmium- and ruthenium-antimony carbonyl clusters and rings |
| title_full_unstemmed |
Osmium- and ruthenium-antimony carbonyl clusters and rings |
| title_sort |
osmium- and ruthenium-antimony carbonyl clusters and rings |
| publishDate |
2016 |
| url |
https://hdl.handle.net/10356/65872 |
| _version_ |
1759853906670649344 |