Fabrication of iron carbide by plasma-enhanced atomic layer deposition

Fabrication of iron carbide by plasma-enhanced atomic layer deposition

Iron carbide (Fe 1− x C x ) thin films were successfully grown by plasma-enhanced atomic layer deposition (PEALD) using bis( N, N ′-di- tert -butylacetamidinato)iron(II) as a precursor and H 2 plasma as a reactant. Smooth and pure Fe 1− x C x thin films were obtained by the PEALD process in a layer-...

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Veröffentlicht in:Journal of materials research 2020-04, Vol.35 (7), p.813-821
Hauptverfasser: Tian, Xu, Zhang, Xiangyu, Hu, Yulian, Liu, Bowen, Yuan, Yuxia, Yang, Lizhen, Chen, Qiang, Liu, Zhongwei
Format: Artikel
Sprache:eng
Schlagworte:
Aluminum
Applied and Technical Physics
Atomic layer epitaxy
Biomaterials
Carbon
Casting
Chemical bonds
Cloth
Crystal structure
Electrodes
Film growth
Glass substrates
Hydrogen evolution
Inorganic Chemistry
Iron carbides
Materials Engineering
Materials research
Materials Science
Metals
Nanotechnology
Plasma
Power
Scanning electron microscopy
Silicon nitride
Thin films
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Zusammenfassung:Iron carbide (Fe 1− x C x ) thin films were successfully grown by plasma-enhanced atomic layer deposition (PEALD) using bis( N, N ′-di- tert -butylacetamidinato)iron(II) as a precursor and H 2 plasma as a reactant. Smooth and pure Fe 1− x C x thin films were obtained by the PEALD process in a layer-by-layer film growth fashion, and the x in the nominal formula of Fe 1− x C x is approximately 0.26. For the wide PEALD temperature window from 80 to 210 °C, a saturated film growth rate of 0.04 nm/cycle was achieved. X-ray diffraction and transition electron microscope measurements show that the films grown at deposition temperature 80–170 °C are amorphous; however, at 210 °C, the crystal structure of Fe 7 C 3 is formed. The conformality and resistivity of the deposited films have also been studied. At last, the PEALD Fe 1− x C x on carbon cloth shows excellent electrocatalytic performance for hydrogen evolution.
ISSN:0884-2914
2044-5326
DOI:10.1557/jmr.2019.332