Graphene layers fabricated from the Ni/a-SiC bilayer precursor

Домашня сторінка
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Фізико-технічні та математичні науки
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Відділення фізики і астрономії
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Semiconductor Physics Quantum Electronics & Optoelectronics
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Semiconductor Physics Quantum Electronics & Optoelectronics, 2013, том 16
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Semicond. Physics Quantum Electronics & Optoelectronics, 2013, № 4
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Graphene layers fabricated from the Ni/a-SiC bilayer precursor

Nazarov, A.N. ; Vasin, A.V. ; Gordienko, S.O. ; Lytvyn, P.M. ; Strelchuk, V.V. ; Nikolenko, A.S. ; Stubrov, Yu.Yu. ; Hirov, A.S. ; Rusavsky, A.V. ; Popov, V.P. ; Lysenko, V.S.

Інший ID: PACS 68.37.Ps, 78.67.Wj

URI: http://dspace.nbuv.gov.ua/handle/123456789/117818

Посилання: Graphene layers fabricated from the Ni/a-SiC bilayer precursor / A.N. Nazarov, A.V. Vasin, S.O. Gordienko, P.M. Lytvyn, V.V. Strelchuk, A.S. Nikolenko, Yu.Yu. Stubrov, A.S. Hirov, A.V. Rusavsky, V.P. Popov, V.S. Lysenko // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2013. — Т. 16, № 4. — С. 322-330. — Бібліогр.: 14 назв. — англ.

Підтримка: This work was supported by the National Academy of Sciences of Ukraine in the framework of the Ukrainian-Russia project No. 39-02-13, the State Program of Ukraine “Nanotechnologies and Nanomaterials” through the Project #3.5.2.6/48 and SFFR Project F53/161-2013.

Дата: 2013

Завантажень: 544

Graphene layers fabricated from the Ni/a-SiC bilayer precursor

Анотація:

This paper considers a synthesis of graphene flakes on the Ni surface by vacuum long and nitrogen rapid thermal treatment of the “sandwich” amorphous (a) SiC/Ni multilayer deposited on silicon wafer by magnetron sputtering technique. The lateral size of graphene flakes was estimated to be about hundreds of micrometers while the thickness estimated using Raman scattering varied from one to few layers in case of vacuum annealing. Rapid thermal annealing (RTA) in nitrogen ambient results in formation of multilayer graphene with surface covering up to 80%. The graphene layers synthesized on Ni during CVD process was used as reference samples. Atomic force microscopy (AFM) is not able to detect graphene flakes in regime of surface topology examination because of large roughness of Ni surface. Employment of scanning Kelvin probe force microscopy (SKPFM) demonstrates correlation of the surface potential and graphene flakes visible in optical microscopy. Using the KPFM method, potential differences between Ni and graphene were determined.

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