4.6 Article

Formation of graphitic films on Cu(111) via electron beam induced deposition

Journal

VACUUM
Volume 183, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.vacuum.2020.109824

Keywords

Thin graphitic films; Electron beam induced deposition (EBID); Auger electron spectroscopy (AES); Electron energy loss spectroscopy (EELS); Scanning tunneling microscopy (STM); Raman spectroscopy

Funding

  1. CONICET through PIP grants [11220150100546, 11220150100675]
  2. Universidad Nacional del Litoral through CAI + D grant [27106005414]

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Electron beam induced deposition using ethylene as precursor gas is utilized to produce carbonaceous films on Cu (111). The study investigates two different precursor gas pressures and two substrate temperatures, finding that lower substrate temperature and higher ethylene pressure lead to optimal film growth conditions. Additionally, ex-situ techniques such as Raman spectroscopy and scanning tunneling spectroscopy show that the film consists of small nanocrystals of few layers graphene.
Electron beam induced deposition using ethylene as precursor gas is used to generate carbonaceous films on Cu (111). The study was performed in an ultrahigh vacuum chamber for two different precursor gas pressures, and two substrate temperatures. Auger electron spectroscopy and reflection electron energy loss spectroscopy were used to characterize the film growth process in-situ. These techniques allowed us to determine how the deposited film covers the Cu(111) substrate as a function of the ethylene exposure, obtaining a final coverage of up to 0.8 monolayer, depending on the growing conditions. Based on the C-KLL Auger line shape and on the reflection electron energy loss (REELS) spectra we can conclude on the graphitic characteristics of the grown film and on the optimum growing conditions: lower substrate temperature and higher ethylene pressure. Raman spectroscopy and scanning tunneling spectroscopy were used as ex-situ techniques to assess the properties of the grown film. Results from both techniques indicate that the film consists of small (10-20 nm in size) nanocrystals of few (1-2) layers graphene. Once optimized, this method may allow growing graphene with a predesigned pattern, without the need to heat the substrate at high temperatures.

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