Direct deposition of multilayer graphene on dielectrics via solid-phase precipitation from carbon-doped cobalt with a copper capping layer

Kazuyoshi Ueno; Shota Sano; Yuji Matsumoto

doi:10.7567/1347-4065/aaf991

Direct deposition of multilayer graphene on dielectrics via solid-phase precipitation from carbon-doped cobalt with a copper capping layer

Kazuyoshi Ueno, Shota Sano, Yuji Matsumoto

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

9 Citations (Scopus)

Abstract

A method for producing a uniform multilayer graphene (MLG) film directly on SiO₂ via solid-phase precipitation from carbon-doped cobalt (Co-C) with a Cu capping layer has been developed for a large scale integration (LSI) interconnect application. One advantage is that no transfer process is required. A 20 nm thick MLG film was grown uniformly from a 100 nm thick Co-C (20 at%) catalyst layer with a Cu capping layer. Cross-sectional TEM/EDX images revealed that the optimized Cu capping layer prevents Co agglomeration during annealing and promotes C precipitation on the SiO₂ while eliminating it on the top surface of the catalytic metals.

Original language	English
Article number	026501
Journal	Japanese Journal of Applied Physics
Volume	58
Issue number	2
DOIs	https://doi.org/10.7567/1347-4065/aaf991
Publication status	Published - 2019

ASJC Scopus subject areas

Engineering(all)
Physics and Astronomy(all)

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title = "Direct deposition of multilayer graphene on dielectrics via solid-phase precipitation from carbon-doped cobalt with a copper capping layer",

abstract = "A method for producing a uniform multilayer graphene (MLG) film directly on SiO2 via solid-phase precipitation from carbon-doped cobalt (Co-C) with a Cu capping layer has been developed for a large scale integration (LSI) interconnect application. One advantage is that no transfer process is required. A 20 nm thick MLG film was grown uniformly from a 100 nm thick Co-C (20 at%) catalyst layer with a Cu capping layer. Cross-sectional TEM/EDX images revealed that the optimized Cu capping layer prevents Co agglomeration during annealing and promotes C precipitation on the SiO2 while eliminating it on the top surface of the catalytic metals.",

author = "Kazuyoshi Ueno and Shota Sano and Yuji Matsumoto",

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N2 - A method for producing a uniform multilayer graphene (MLG) film directly on SiO2 via solid-phase precipitation from carbon-doped cobalt (Co-C) with a Cu capping layer has been developed for a large scale integration (LSI) interconnect application. One advantage is that no transfer process is required. A 20 nm thick MLG film was grown uniformly from a 100 nm thick Co-C (20 at%) catalyst layer with a Cu capping layer. Cross-sectional TEM/EDX images revealed that the optimized Cu capping layer prevents Co agglomeration during annealing and promotes C precipitation on the SiO2 while eliminating it on the top surface of the catalytic metals.

AB - A method for producing a uniform multilayer graphene (MLG) film directly on SiO2 via solid-phase precipitation from carbon-doped cobalt (Co-C) with a Cu capping layer has been developed for a large scale integration (LSI) interconnect application. One advantage is that no transfer process is required. A 20 nm thick MLG film was grown uniformly from a 100 nm thick Co-C (20 at%) catalyst layer with a Cu capping layer. Cross-sectional TEM/EDX images revealed that the optimized Cu capping layer prevents Co agglomeration during annealing and promotes C precipitation on the SiO2 while eliminating it on the top surface of the catalytic metals.

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Direct deposition of multilayer graphene on dielectrics via solid-phase precipitation from carbon-doped cobalt with a copper capping layer

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