Investigation of Thermal Annealing Effect on Bilayer Graphene by Isotope‐Labeling‐Assisted Raman Spectroscopy

physica status solidi (b) Pub Date : 2020-10-29 DOI:10.1002/pssb.202000250

Jinglan Liu, Xuewei Zhang, Yanhan Jin, Yang Zhang, Zilong Zhang, Yangyang Xia, P. Zhao, Hongtao Wang

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引用次数: 1

Abstract

Thermal annealing is a necessary step in the standard fabrication process of graphene for removal of polymethyl methacrylate (PMMA). The influence of thermal annealing on monolayer graphene (MLG) has been intensively studied, but that on bilayer graphene (BLG) remains unclear. A key challenge for such investigation is that the Raman spectroscopic method that is usually used on MLG encounters the overlap of featured peaks from the two graphene layers. Herein, the independent featured Raman peaks of the two layers can be detected using isotope‐labeled BLG samples, so that the shift in each spectrum affected by the annealing process can be monitored. Results show that there are compression and doping in MLG and twisted‐stacked BLG (t‐BLG) after annealing. Compared with that in MLG, the annealing‐induced doping level in the adlayer of t‐BLG is lower, and in the top layer of t‐BLG, only a low level of doping and compression remains after thermal annealing. Moreover, the annealing‐induced doping level in AB‐stacked BLG (AB‐BLG) is almost the same with that in t‐BLG, and the originally induced compression during a transfer process is unloaded. These results can provide more understanding for the post‐treatment of graphene on substrates and the characterization of each layer.

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用同位素标记辅助拉曼光谱研究双层石墨烯的热退火效应

热退火是石墨烯标准制备工艺中去除聚甲基丙烯酸甲酯(PMMA)的必要步骤。热退火对单层石墨烯(MLG)的影响已被深入研究，但对双层石墨烯(BLG)的影响尚不清楚。这种研究的一个关键挑战是，通常用于MLG的拉曼光谱方法会遇到来自两个石墨烯层的特征峰重叠。在这里，可以使用同位素标记的BLG样品检测两层的独立特征拉曼峰，因此可以监测退火过程影响的每个光谱的位移。结果表明，MLG和扭曲堆叠BLG (t - BLG)在退火后存在压缩和掺杂现象。与MLG相比，t - BLG下层的退火诱导掺杂水平较低，热退火后t - BLG顶层的掺杂和压缩水平较低。此外，AB‐堆叠BLG (AB‐BLG)中退火诱导的掺杂水平与t‐BLG中几乎相同，并且在转移过程中原始诱导的压缩被卸载。这些结果可以为石墨烯在衬底上的后处理和每层的表征提供更多的理解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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physica status solidi (b)

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