Four-electron reduction of benzene by a samarium(ii)-alkyl without the addition of external reducing agents

Georgia M. Richardson; Thayalan Rajeshkumar; Finlay M. Burke; Scott A. Cameron; Brooke D. Nicholls; Joanne E. Harvey; Robert A. Keyzers; Tane Butler; Simon Granville; Lujia Liu; Julien Langley; Li F. Lim; Nicholas Cox; Nicholas F. Chilton; Jamie Hicks; Nathaniel J.L.K. Davis; Laurent Maron; Mathew D. Anker

doi:10.1038/s41557-024-01688-6

Four-electron reduction of benzene by a samarium(ii)-alkyl without the addition of external reducing agents

Georgia M. Richardson, Thayalan Rajeshkumar, Finlay M. Burke, Scott A. Cameron, Brooke D. Nicholls, Joanne E. Harvey, Robert A. Keyzers, Tane Butler, Simon Granville, Lujia Liu, Julien Langley, Li F. Lim, Nicholas Cox, Nicholas F. Chilton, Jamie Hicks, Nathaniel J.L.K. Davis, Laurent Maron^*, Mathew D. Anker^*

^*Corresponding author for this work

Research School of Chemistry

Research output: Contribution to journal › Article › peer-review

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Abstract

Benzene reduction by molecular complexes remains an important synthetic challenge, requiring harsh reaction conditions involving group I metals. Reductions of benzene, to date, typically result in a loss of aromaticity, although the benzene tetra-anion, a 10π-electron system, has been calculated to be stable and aromatic. Due to the lack of sufficiently potent reductants, four-electron reduction of benzene usually requires the use of group I metals. Here we demonstrate the four-electron reduction of benzene and some of its derivatives using a samarium(ii) alkyl reagent, with no requirement for group I metals. Whereas organosamarium(ii) typically reacts through one-electron processes, the compounds reported here feature a rare two-electron process. Combined experimental and computational results implicate a transient samarium(i) intermediate involved in this reduction process, which ultimately provides the benzene tetra-anion. The remarkably strong reducing power of this samarium(ii) alkyl implies a rich reactivity, providing scope for its application as a reducing agent. (Figure presented.)

Original language	English
Article number	1448
Pages (from-to)	20-28
Number of pages	9
Journal	Nature Chemistry
Volume	17
DOIs	https://doi.org/10.1038/s41557-024-01688-6
Publication status	Published - 3 Jan 2025

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Richardson, G. M., Rajeshkumar, T., Burke, F. M., Cameron, S. A., Nicholls, B. D., Harvey, J. E., Keyzers, R. A., Butler, T., Granville, S., Liu, L., Langley, J., Lim, L. F., Cox, N., Chilton, N. F., Hicks, J., Davis, N. J. L. K., Maron, L., & Anker, M. D. (2025). Four-electron reduction of benzene by a samarium(ii)-alkyl without the addition of external reducing agents. Nature Chemistry, 17, 20-28. Article 1448. https://doi.org/10.1038/s41557-024-01688-6

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title = "Four-electron reduction of benzene by a samarium(ii)-alkyl without the addition of external reducing agents",

abstract = "Benzene reduction by molecular complexes remains an important synthetic challenge, requiring harsh reaction conditions involving group I metals. Reductions of benzene, to date, typically result in a loss of aromaticity, although the benzene tetra-anion, a 10π-electron system, has been calculated to be stable and aromatic. Due to the lack of sufficiently potent reductants, four-electron reduction of benzene usually requires the use of group I metals. Here we demonstrate the four-electron reduction of benzene and some of its derivatives using a samarium(ii) alkyl reagent, with no requirement for group I metals. Whereas organosamarium(ii) typically reacts through one-electron processes, the compounds reported here feature a rare two-electron process. Combined experimental and computational results implicate a transient samarium(i) intermediate involved in this reduction process, which ultimately provides the benzene tetra-anion. The remarkably strong reducing power of this samarium(ii) alkyl implies a rich reactivity, providing scope for its application as a reducing agent. (Figure presented.)",

author = "Richardson, {Georgia M.} and Thayalan Rajeshkumar and Burke, {Finlay M.} and Cameron, {Scott A.} and Nicholls, {Brooke D.} and Harvey, {Joanne E.} and Keyzers, {Robert A.} and Tane Butler and Simon Granville and Lujia Liu and Julien Langley and Lim, {Li F.} and Nicholas Cox and Chilton, {Nicholas F.} and Jamie Hicks and Davis, {Nathaniel J.L.K.} and Laurent Maron and Anker, {Mathew D.}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2024.",

year = "2025",

month = jan,

day = "3",

doi = "10.1038/s41557-024-01688-6",

language = "English",

volume = "17",

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journal = "Nature Chemistry",

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Richardson, GM, Rajeshkumar, T, Burke, FM, Cameron, SA, Nicholls, BD, Harvey, JE, Keyzers, RA, Butler, T, Granville, S, Liu, L, Langley, J, Lim, LF , Cox, N , Chilton, NF , Hicks, J, Davis, NJLK, Maron, L & Anker, MD 2025, 'Four-electron reduction of benzene by a samarium(ii)-alkyl without the addition of external reducing agents', Nature Chemistry, vol. 17, 1448, pp. 20-28. https://doi.org/10.1038/s41557-024-01688-6

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T1 - Four-electron reduction of benzene by a samarium(ii)-alkyl without the addition of external reducing agents

AU - Richardson, Georgia M.

AU - Rajeshkumar, Thayalan

AU - Burke, Finlay M.

AU - Cameron, Scott A.

AU - Nicholls, Brooke D.

AU - Harvey, Joanne E.

AU - Keyzers, Robert A.

AU - Butler, Tane

AU - Granville, Simon

AU - Liu, Lujia

AU - Langley, Julien

AU - Lim, Li F.

AU - Cox, Nicholas

AU - Chilton, Nicholas F.

AU - Hicks, Jamie

AU - Davis, Nathaniel J.L.K.

AU - Maron, Laurent

AU - Anker, Mathew D.

PY - 2025/1/3

Y1 - 2025/1/3

N2 - Benzene reduction by molecular complexes remains an important synthetic challenge, requiring harsh reaction conditions involving group I metals. Reductions of benzene, to date, typically result in a loss of aromaticity, although the benzene tetra-anion, a 10π-electron system, has been calculated to be stable and aromatic. Due to the lack of sufficiently potent reductants, four-electron reduction of benzene usually requires the use of group I metals. Here we demonstrate the four-electron reduction of benzene and some of its derivatives using a samarium(ii) alkyl reagent, with no requirement for group I metals. Whereas organosamarium(ii) typically reacts through one-electron processes, the compounds reported here feature a rare two-electron process. Combined experimental and computational results implicate a transient samarium(i) intermediate involved in this reduction process, which ultimately provides the benzene tetra-anion. The remarkably strong reducing power of this samarium(ii) alkyl implies a rich reactivity, providing scope for its application as a reducing agent. (Figure presented.)

AB - Benzene reduction by molecular complexes remains an important synthetic challenge, requiring harsh reaction conditions involving group I metals. Reductions of benzene, to date, typically result in a loss of aromaticity, although the benzene tetra-anion, a 10π-electron system, has been calculated to be stable and aromatic. Due to the lack of sufficiently potent reductants, four-electron reduction of benzene usually requires the use of group I metals. Here we demonstrate the four-electron reduction of benzene and some of its derivatives using a samarium(ii) alkyl reagent, with no requirement for group I metals. Whereas organosamarium(ii) typically reacts through one-electron processes, the compounds reported here feature a rare two-electron process. Combined experimental and computational results implicate a transient samarium(i) intermediate involved in this reduction process, which ultimately provides the benzene tetra-anion. The remarkably strong reducing power of this samarium(ii) alkyl implies a rich reactivity, providing scope for its application as a reducing agent. (Figure presented.)

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SP - 20

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JO - Nature Chemistry

JF - Nature Chemistry

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Four-electron reduction of benzene by a samarium(ii)-alkyl without the addition of external reducing agents

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