金属催化辅助无转移石墨烯薄膜制备技术研究进展

doi:10.11896/cldb.23050126

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Abstract As a kind of atomic thin two-dimensional materials with a hexagonal honeycomb structure of carbon atoms, graphene exhibits exceptional electronic, optical and thermal properties and attracts worldwide interests for related functional device applications. Before the integration of semiconductor devices, high-quality and single crystal graphene is prerequisite for scientific research and practical application. Due to the sophisticated and time-consuming post-transferring procedure, metal-catalyzed synthesis of graphene films based on the chemical vapor deposition more or less introduces structural defects (cracks, winkles and tears) and degrades the intrinsic superb properties of graphene. Growth of graphene films on dielectric substrates, therefore, plays a significant role in the large-scale functional applications of graphene. Metal-assisted transfer-free synthesis of graphene on the dielectric substrates has achieved high-level accomplishment and gained excellent detector response in the devices. Unfortunately, the microstructural mechanism and design strategy of metal catalyst in the transfer-free graphene film growth have not been clear and systematical elucidated. Given all that we try to interpret and conclude the effects and design of metal catalysts motivated the direct synthesis of graphene film on non-catalytic substrates in this paper. These comprehensive analyses will provide a valuable guidance for the application of graphene film in electronic, optoelectronic and even thermo-response devices.

Key words： graphene film transfer-free synthesis metal catalyst dielectric substrates

Published: 10 August 2024 Online: 2024-08-29

CLC number:

TQ127

Fund:National Natural Science Foundation of China (52171144).

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	Articles by authors
	HUANG Yong
	GUO Chongxiao
	NI Jiamiao
	LIU Yue
	FAN Tongxiang

Cite this article:

HUANG Yong,GUO Chongxiao,NI Jiamiao, et al. Progress in the Synthesis of Transfer-Free Graphene Films with Metal Catalyst[J]. Materials Reports, 2024, 38(15): 23050126-15.

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http://www.mater-rep.com/EN/10.11896/cldb.23050126 OR http://www.mater-rep.com/EN/Y2024/V38/I15/23050126

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