Raman Spectral Band Oscillations in Large Graphene Bubbles

Yuan Huang; Xiao Wang; Xu Zhang; Xianjue Chen; Baowen Li; Bin Wang; Ming Huang; Chongyang Zhu; Xuewei Zhang; Wolfgang S. Bacsa; Feng Ding; Rodney S. Ruoff

doi:10.1103/PhysRevLett.120.186104

Raman Spectral Band Oscillations in Large Graphene Bubbles

Yuan Huang, Xiao Wang, Xu Zhang, Xianjue Chen, Baowen Li, Bin Wang, Ming Huang, Chongyang Zhu, Xuewei Zhang, Wolfgang S. Bacsa, Feng Ding, Rodney S. Ruoff

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

46 Citations (Scopus)

Abstract

Raman spectra of large graphene bubbles showed size-dependent oscillations in spectral intensity and frequency, which originate from optical standing waves formed in the vicinity of the graphene surface. At a high laser power, local heating can lead to oscillations in the Raman frequency and also create a temperature gradient in the bubble. Based on Raman data, the temperature distribution within the graphene bubble was calculated, and it is shown that the heating effect of the laser is reduced when moving from the center of a bubble to its edge. By studying graphene bubbles, both the thermal conductivity and chemical reactivity of graphene were assessed. When exposed to hydrogen plasma, areas with bubbles are found to be more reactive than flat graphene.

Original language	English
Article number	186104
Journal	Physical Review Letters
Volume	120
Issue number	18
DOIs	https://doi.org/10.1103/PhysRevLett.120.186104
Publication status	Published - 3 May 2018
Externally published	Yes

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title = "Raman Spectral Band Oscillations in Large Graphene Bubbles",

abstract = "Raman spectra of large graphene bubbles showed size-dependent oscillations in spectral intensity and frequency, which originate from optical standing waves formed in the vicinity of the graphene surface. At a high laser power, local heating can lead to oscillations in the Raman frequency and also create a temperature gradient in the bubble. Based on Raman data, the temperature distribution within the graphene bubble was calculated, and it is shown that the heating effect of the laser is reduced when moving from the center of a bubble to its edge. By studying graphene bubbles, both the thermal conductivity and chemical reactivity of graphene were assessed. When exposed to hydrogen plasma, areas with bubbles are found to be more reactive than flat graphene.",

author = "Yuan Huang and Xiao Wang and Xu Zhang and Xianjue Chen and Baowen Li and Bin Wang and Ming Huang and Chongyang Zhu and Xuewei Zhang and Bacsa, {Wolfgang S.} and Feng Ding and Ruoff, {Rodney S.}",

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AU - Huang, Yuan

AU - Wang, Xiao

AU - Zhang, Xu

AU - Chen, Xianjue

AU - Li, Baowen

AU - Wang, Bin

AU - Huang, Ming

AU - Zhu, Chongyang

AU - Zhang, Xuewei

AU - Bacsa, Wolfgang S.

AU - Ding, Feng

AU - Ruoff, Rodney S.

PY - 2018/5/3

Y1 - 2018/5/3

N2 - Raman spectra of large graphene bubbles showed size-dependent oscillations in spectral intensity and frequency, which originate from optical standing waves formed in the vicinity of the graphene surface. At a high laser power, local heating can lead to oscillations in the Raman frequency and also create a temperature gradient in the bubble. Based on Raman data, the temperature distribution within the graphene bubble was calculated, and it is shown that the heating effect of the laser is reduced when moving from the center of a bubble to its edge. By studying graphene bubbles, both the thermal conductivity and chemical reactivity of graphene were assessed. When exposed to hydrogen plasma, areas with bubbles are found to be more reactive than flat graphene.

AB - Raman spectra of large graphene bubbles showed size-dependent oscillations in spectral intensity and frequency, which originate from optical standing waves formed in the vicinity of the graphene surface. At a high laser power, local heating can lead to oscillations in the Raman frequency and also create a temperature gradient in the bubble. Based on Raman data, the temperature distribution within the graphene bubble was calculated, and it is shown that the heating effect of the laser is reduced when moving from the center of a bubble to its edge. By studying graphene bubbles, both the thermal conductivity and chemical reactivity of graphene were assessed. When exposed to hydrogen plasma, areas with bubbles are found to be more reactive than flat graphene.

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DO - 10.1103/PhysRevLett.120.186104

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VL - 120

JO - Physical Review Letters

JF - Physical Review Letters

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Raman Spectral Band Oscillations in Large Graphene Bubbles

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