Отправить статью по E-mail Cobalt Intercalation of Graphene on Silicon Carbide
- Авторы: Grebenyuk G.S.1, Lobanova E.Y.2, Smirnov D.A.3,4, Eliseev I.A.1, Zubov A.V.2, Smirnov A.N.1, Lebedev S.P.1, Davydov V.Y.1, Lebedev A.A.1, Pronin I.I.1,2
-
Учреждения:
- Ioffe Institute
- St. Petersburg National Research University of Information Technologies, Mechanics, and Optics
- St. Petersburg State University
- Institute of Solid State Physics, Dresden University of Technology
- Выпуск: Том 61, № 7 (2019)
- Страницы: 1316-1326
- Раздел: Surface Physics and Thin Films
- URL: https://journals.rcsi.science/1063-7834/article/view/205959
- DOI: https://doi.org/10.1134/S1063783419070102
- ID: 205959
Цитировать
Открытый доступ
Доступ предоставлен
Только для подписчиков
Аннотация
In this paper, we studied cobalt intercalation of single-layer graphene grown on the 4H-SiC(0001) polytype. The experiments were carried out in situ under ultrahigh vacuum conditions by high energy resolution photoelectron spectroscopy using synchrotron radiation and low energy electron diffraction. The nominal thicknesses of the deposited cobalt layers varied in the range of 0.2–5 nm, while the sample temperature was varied from room temperature to 800°C. Unlike Fe films, the annealing of Co films deposited on graphene at room temperature is shown to not intercalate graphene by cobalt. The formation of the graphene–cobalt–SiC intercalation system was detected upon deposition of Co atoms on samples heated to temperatures of above ~400°C. Cobalt films with a thickness up to 2 nm under graphene are formed using this method, and they are shown to be magnetized along the surface at thicknesses of greater than 1.3 nm. Graphene intercalation by cobalt was found to be accompanied by the chemical interaction of Co atoms with silicon carbide leading to the synthesis of cobalt silicides. At temperatures of above 500°C, the growth of cobalt films under graphene is limited by the diffusion of Co atoms into the bulk of silicon carbide.
Об авторах
G. Grebenyuk
Ioffe Institute
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 194021
E. Lobanova
St. Petersburg National Research University of Information Technologies, Mechanics, and Optics
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 197101
D. Smirnov
St. Petersburg State University; Institute of Solid State Physics, Dresden University of Technology
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 199034; Dresden, 01069
I. Eliseev
Ioffe Institute
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 194021
A. Zubov
St. Petersburg National Research University of Information Technologies, Mechanics, and Optics
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 197101
A. Smirnov
Ioffe Institute
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 194021
S. Lebedev
Ioffe Institute
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 194021
V. Davydov
Ioffe Institute
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 194021
A. Lebedev
Ioffe Institute
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 194021
I. Pronin
Ioffe Institute; St. Petersburg National Research University of Information Technologies, Mechanics, and Optics
Автор, ответственный за переписку.
Email: Igor.Pronin@mail.ioffe.ru
Россия, St. Petersburg, 194021; St. Petersburg, 197101
Дополнительные файлы
