The sputtering of graphite due to the bombardment of hydrogen isotopes is crucial to successfully using graphite in the fusion environment. In this work, we use molecular dynamics to simulate the sputtering using the large-scale atomic/molecular massively parallel simulator (lammps). The calculation results show that the peak values of the sputtering yield are between 25 eV and 50 eV. When the incident energy is greater than the energy corresponding to the peak value, a lower carbon sputtering yield is obtained. The temperature that is most likely to sputter is approximately 800 K for hydrogen, deuterium, and tritium. Below the 800 K, the sputtering yields increase with temperature. By contrast, above the 800 K, the yields decrease with increasing temperature. Under the same temperature and incident energy, the sputtering rate of tritium is greater than that of deuterium, which in turn is greater than that of hydrogen. When the incident energy is 25 eV, the sputtering yield at 300 K increases below an incident angle at 30 deg and remains steady after that.
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October 2018
Research-Article
Sputtering of Graphite by Hydrogen Isotopes in the Fusion Environment: A Molecular Dynamics Simulation Study
Qiang Zhao,
Qiang Zhao
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Search for other works by this author on:
Yang Li,
Yang Li
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Search for other works by this author on:
Zheng Zhang,
Zheng Zhang
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Search for other works by this author on:
Xiaoping Ouyang
Xiaoping Ouyang
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China;
Northwest Institute of Nuclear Technology,
Xi'an 710024, Shaanxi, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China;
Northwest Institute of Nuclear Technology,
Xi'an 710024, Shaanxi, China
Search for other works by this author on:
Qiang Zhao
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Yang Li
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Zheng Zhang
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China
Xiaoping Ouyang
Beijing Key Laboratory of Passive Safety
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China;
Northwest Institute of Nuclear Technology,
Xi'an 710024, Shaanxi, China
Technology for Nuclear Energy,
North China Electric Power University,
Beijing 102206, China;
Northwest Institute of Nuclear Technology,
Xi'an 710024, Shaanxi, China
Manuscript received October 31, 2017; final manuscript received May 25, 2018; published online September 10, 2018. Assoc. Editor: Dmitry Paramonov.
ASME J of Nuclear Rad Sci. Oct 2018, 4(4): 041022 (4 pages)
Published Online: September 10, 2018
Article history
Received:
October 31, 2017
Revised:
May 25, 2018
Citation
Zhao, Q., Li, Y., Zhang, Z., and Ouyang, X. (September 10, 2018). "Sputtering of Graphite by Hydrogen Isotopes in the Fusion Environment: A Molecular Dynamics Simulation Study." ASME. ASME J of Nuclear Rad Sci. October 2018; 4(4): 041022. https://doi.org/10.1115/1.4040495
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ASME J of Nuclear Rad Sci
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