Birch-Type Hydrogenation of Few-Layer Graphenes: Products and Mechanistic Implications

Xu Zhang; Yuan Huang; Shanshan Chen; Na Yeon Kim; Wontaek Kim; David Schilter; Mandakini Biswal; Baowen Li; Zonghoon Lee; Sunmin Ryu; Christopher W. Bielawski; Wolfgang S. Bacsa; Rodney S. Ruoff

doi:10.1021/jacs.6b08625

Birch-Type Hydrogenation of Few-Layer Graphenes: Products and Mechanistic Implications

Xu Zhang, Yuan Huang, Shanshan Chen, Na Yeon Kim, Wontaek Kim, David Schilter, Mandakini Biswal, Baowen Li, Zonghoon Lee, Sunmin Ryu, Christopher W. Bielawski, Wolfgang S. Bacsa, Rodney S. Ruoff^*

^*此作品的通讯作者

科研成果: 期刊稿件 › 文章 › 同行评审

29 引用（Scopus）

摘要

Few-layer graphenes, supported on Si with a superficial oxide layer, were subjected to a Birch-type reduction using Li and H₂O as the electron and proton donors, respectively. The extent of hydrogenation for bilayer graphene was estimated at 1.6-24.1% according to Raman and X-ray photoelectron spectroscopic data. While single-layer graphene reacts uniformly, few-layer graphenes were hydrogenated inward from the edges and/or defects. The role of these reactive sites was reflected in the inertness of pristine few-layer graphenes whose edges were sealed. Hydrogenation of labeled bilayer (¹²C/¹³C) and trilayer (¹²C/¹³C/¹²C) graphenes afforded products whose sheets were hydrogenated to the same extent, implicating passage of reagents between the graphene layers and equal decoration of each graphene face. The reduction of few-layer graphenes introduces strain, allows tuning of optical transmission and fluorescence, and opens synthetic routes to long sought-after films containing sp³-hybridized carbon.

源语言	英语
页（从-至）	14980-14986
页数	7
期刊	Journal of the American Chemical Society
卷	138
期	45
DOI	https://doi.org/10.1021/jacs.6b08625
出版状态	已出版 - 16 11月 2016
已对外发布	是

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Zhang, X., Huang, Y., Chen, S., Kim, N. Y., Kim, W., Schilter, D., Biswal, M., Li, B., Lee, Z., Ryu, S., Bielawski, C. W., Bacsa, W. S., & Ruoff, R. S. (2016). Birch-Type Hydrogenation of Few-Layer Graphenes: Products and Mechanistic Implications. Journal of the American Chemical Society, 138(45), 14980-14986. https://doi.org/10.1021/jacs.6b08625

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title = "Birch-Type Hydrogenation of Few-Layer Graphenes: Products and Mechanistic Implications",

abstract = "Few-layer graphenes, supported on Si with a superficial oxide layer, were subjected to a Birch-type reduction using Li and H2O as the electron and proton donors, respectively. The extent of hydrogenation for bilayer graphene was estimated at 1.6-24.1% according to Raman and X-ray photoelectron spectroscopic data. While single-layer graphene reacts uniformly, few-layer graphenes were hydrogenated inward from the edges and/or defects. The role of these reactive sites was reflected in the inertness of pristine few-layer graphenes whose edges were sealed. Hydrogenation of labeled bilayer (12C/13C) and trilayer (12C/13C/12C) graphenes afforded products whose sheets were hydrogenated to the same extent, implicating passage of reagents between the graphene layers and equal decoration of each graphene face. The reduction of few-layer graphenes introduces strain, allows tuning of optical transmission and fluorescence, and opens synthetic routes to long sought-after films containing sp3-hybridized carbon.",

author = "Xu Zhang and Yuan Huang and Shanshan Chen and Kim, {Na Yeon} and Wontaek Kim and David Schilter and Mandakini Biswal and Baowen Li and Zonghoon Lee and Sunmin Ryu and Bielawski, {Christopher W.} and Bacsa, {Wolfgang S.} and Ruoff, {Rodney S.}",

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AU - Zhang, Xu

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AU - Kim, Wontaek

AU - Schilter, David

AU - Biswal, Mandakini

AU - Li, Baowen

AU - Lee, Zonghoon

AU - Ryu, Sunmin

AU - Bielawski, Christopher W.

AU - Bacsa, Wolfgang S.

AU - Ruoff, Rodney S.

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N2 - Few-layer graphenes, supported on Si with a superficial oxide layer, were subjected to a Birch-type reduction using Li and H2O as the electron and proton donors, respectively. The extent of hydrogenation for bilayer graphene was estimated at 1.6-24.1% according to Raman and X-ray photoelectron spectroscopic data. While single-layer graphene reacts uniformly, few-layer graphenes were hydrogenated inward from the edges and/or defects. The role of these reactive sites was reflected in the inertness of pristine few-layer graphenes whose edges were sealed. Hydrogenation of labeled bilayer (12C/13C) and trilayer (12C/13C/12C) graphenes afforded products whose sheets were hydrogenated to the same extent, implicating passage of reagents between the graphene layers and equal decoration of each graphene face. The reduction of few-layer graphenes introduces strain, allows tuning of optical transmission and fluorescence, and opens synthetic routes to long sought-after films containing sp3-hybridized carbon.

AB - Few-layer graphenes, supported on Si with a superficial oxide layer, were subjected to a Birch-type reduction using Li and H2O as the electron and proton donors, respectively. The extent of hydrogenation for bilayer graphene was estimated at 1.6-24.1% according to Raman and X-ray photoelectron spectroscopic data. While single-layer graphene reacts uniformly, few-layer graphenes were hydrogenated inward from the edges and/or defects. The role of these reactive sites was reflected in the inertness of pristine few-layer graphenes whose edges were sealed. Hydrogenation of labeled bilayer (12C/13C) and trilayer (12C/13C/12C) graphenes afforded products whose sheets were hydrogenated to the same extent, implicating passage of reagents between the graphene layers and equal decoration of each graphene face. The reduction of few-layer graphenes introduces strain, allows tuning of optical transmission and fluorescence, and opens synthetic routes to long sought-after films containing sp3-hybridized carbon.

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Birch-Type Hydrogenation of Few-Layer Graphenes: Products and Mechanistic Implications

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