Conjugatively Stabilized Bridgehead Olefins: Formation and Reaction of Remarkably Stable Homoadamant-3-enes Substituted with Phenyl and Methoxycarbonyl Groups

Conjugatively stabilized double bonds were formed at the bridgehead of homoadamantane by way of the 1,2-carbon shift of adamantylcarbene (-carbenoid) intermediates generated from decomposition of the diazo precursors (1-adamantyl)diazophenylmethane (7) and methyl (1-adamantyl)diazoacetate (10). Deco...

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Veröffentlicht in:	Journal of the American Chemical Society 1996-07, Vol.118 (30), p.7075-7082
Hauptverfasser:	Ohno, Masatomi, Itoh, Motohiro, Umeda, Masami, Furuta, Ryoji, Kondo, Kazumoto, Eguchi, Shoji
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creator	Ohno, Masatomi Itoh, Motohiro Umeda, Masami Furuta, Ryoji Kondo, Kazumoto Eguchi, Shoji
description	Conjugatively stabilized double bonds were formed at the bridgehead of homoadamantane by way of the 1,2-carbon shift of adamantylcarbene (-carbenoid) intermediates generated from decomposition of the diazo precursors (1-adamantyl)diazophenylmethane (7) and methyl (1-adamantyl)diazoacetate (10). Decomposition to 4-phenyl- and 4-methoxycarbonyl-substituted homoadamant-3-enes 1 and 2 was much more efficient via catalysis with Rh2(OAc)4 in dichloromethane than by photolysis or thermolysis (FVP; in the case of 7, indane-fused homoadamantane was produced by a phenylcarbene rearrangement followed by insertion to a bridged methylene). In the Rh catalysis, reactions of 7 and 10 in hexane and with Rh2(NHCOCH3)4 did not promote the formation of 1 and 2, suggesting that the polarized structure of the Rh−carbene complex participated in the 1,2-carbon shift. The substituted bridgehead olefins were considerably stable even at 0 °C to room temperature (more than half of 1 and 2 survived in solution at room temperature after 12 and 1 h, respectively), while parent homoadamant-3-ene was recorded to be unstable at −20 °C. Therefore, after decomposition of the diazo precursors was complete, reagents (electrophies for 1 and nucleophiles for 2) were allowed to react at these temperatures to give 3,4-disubstituted homoadamantane derivatives, including some cycloadducts. With atmospheric oxygen, addition and subsequent bond cleavage occurred smoothly to give bicyclo[3.3.1]nonanones. The remarkable stability of 1 and 2 was considered to be the result of conjugation with the substituents, along with some steric protection, which allowed the polarized structure to have a greater effect in reducing the strain energy. This notion was verified by examining longer carbon−carbon double bonds using spectroscopy and PM3 calculations.
doi_str_mv	10.1021/ja953977q
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Decomposition to 4-phenyl- and 4-methoxycarbonyl-substituted homoadamant-3-enes 1 and 2 was much more efficient via catalysis with Rh2(OAc)4 in dichloromethane than by photolysis or thermolysis (FVP; in the case of 7, indane-fused homoadamantane was produced by a phenylcarbene rearrangement followed by insertion to a bridged methylene). In the Rh catalysis, reactions of 7 and 10 in hexane and with Rh2(NHCOCH3)4 did not promote the formation of 1 and 2, suggesting that the polarized structure of the Rh−carbene complex participated in the 1,2-carbon shift. The substituted bridgehead olefins were considerably stable even at 0 °C to room temperature (more than half of 1 and 2 survived in solution at room temperature after 12 and 1 h, respectively), while parent homoadamant-3-ene was recorded to be unstable at −20 °C. Therefore, after decomposition of the diazo precursors was complete, reagents (electrophies for 1 and nucleophiles for 2) were allowed to react at these temperatures to give 3,4-disubstituted homoadamantane derivatives, including some cycloadducts. With atmospheric oxygen, addition and subsequent bond cleavage occurred smoothly to give bicyclo[3.3.1]nonanones. The remarkable stability of 1 and 2 was considered to be the result of conjugation with the substituents, along with some steric protection, which allowed the polarized structure to have a greater effect in reducing the strain energy. 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Am. Chem. Soc</addtitle><description>Conjugatively stabilized double bonds were formed at the bridgehead of homoadamantane by way of the 1,2-carbon shift of adamantylcarbene (-carbenoid) intermediates generated from decomposition of the diazo precursors (1-adamantyl)diazophenylmethane (7) and methyl (1-adamantyl)diazoacetate (10). Decomposition to 4-phenyl- and 4-methoxycarbonyl-substituted homoadamant-3-enes 1 and 2 was much more efficient via catalysis with Rh2(OAc)4 in dichloromethane than by photolysis or thermolysis (FVP; in the case of 7, indane-fused homoadamantane was produced by a phenylcarbene rearrangement followed by insertion to a bridged methylene). In the Rh catalysis, reactions of 7 and 10 in hexane and with Rh2(NHCOCH3)4 did not promote the formation of 1 and 2, suggesting that the polarized structure of the Rh−carbene complex participated in the 1,2-carbon shift. The substituted bridgehead olefins were considerably stable even at 0 °C to room temperature (more than half of 1 and 2 survived in solution at room temperature after 12 and 1 h, respectively), while parent homoadamant-3-ene was recorded to be unstable at −20 °C. Therefore, after decomposition of the diazo precursors was complete, reagents (electrophies for 1 and nucleophiles for 2) were allowed to react at these temperatures to give 3,4-disubstituted homoadamantane derivatives, including some cycloadducts. With atmospheric oxygen, addition and subsequent bond cleavage occurred smoothly to give bicyclo[3.3.1]nonanones. The remarkable stability of 1 and 2 was considered to be the result of conjugation with the substituents, along with some steric protection, which allowed the polarized structure to have a greater effect in reducing the strain energy. 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Am. Chem. Soc</addtitle><date>1996-07-31</date><risdate>1996</risdate><volume>118</volume><issue>30</issue><spage>7075</spage><epage>7082</epage><pages>7075-7082</pages><issn>0002-7863</issn><eissn>1520-5126</eissn><abstract>Conjugatively stabilized double bonds were formed at the bridgehead of homoadamantane by way of the 1,2-carbon shift of adamantylcarbene (-carbenoid) intermediates generated from decomposition of the diazo precursors (1-adamantyl)diazophenylmethane (7) and methyl (1-adamantyl)diazoacetate (10). Decomposition to 4-phenyl- and 4-methoxycarbonyl-substituted homoadamant-3-enes 1 and 2 was much more efficient via catalysis with Rh2(OAc)4 in dichloromethane than by photolysis or thermolysis (FVP; in the case of 7, indane-fused homoadamantane was produced by a phenylcarbene rearrangement followed by insertion to a bridged methylene). In the Rh catalysis, reactions of 7 and 10 in hexane and with Rh2(NHCOCH3)4 did not promote the formation of 1 and 2, suggesting that the polarized structure of the Rh−carbene complex participated in the 1,2-carbon shift. The substituted bridgehead olefins were considerably stable even at 0 °C to room temperature (more than half of 1 and 2 survived in solution at room temperature after 12 and 1 h, respectively), while parent homoadamant-3-ene was recorded to be unstable at −20 °C. Therefore, after decomposition of the diazo precursors was complete, reagents (electrophies for 1 and nucleophiles for 2) were allowed to react at these temperatures to give 3,4-disubstituted homoadamantane derivatives, including some cycloadducts. With atmospheric oxygen, addition and subsequent bond cleavage occurred smoothly to give bicyclo[3.3.1]nonanones. The remarkable stability of 1 and 2 was considered to be the result of conjugation with the substituents, along with some steric protection, which allowed the polarized structure to have a greater effect in reducing the strain energy. This notion was verified by examining longer carbon−carbon double bonds using spectroscopy and PM3 calculations.</abstract><pub>American Chemical Society</pub><doi>10.1021/ja953977q</doi><tpages>8</tpages></addata></record>
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title	Conjugatively Stabilized Bridgehead Olefins: Formation and Reaction of Remarkably Stable Homoadamant-3-enes Substituted with Phenyl and Methoxycarbonyl Groups
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