Molecular dynamics simulation of collisions between hydrogen and graphite

ATSUSHI ITO; HIROAKI NAKAMURA

doi:10.1017/S0022377806005289

Abstract

Hydrogen adsorption by graphite is examined by classical molecular dynamics simulation using a modified Brenner reactive empirical bond order (REBO) potential. Such interactions are typical in chemical sputtering experiments, and knowledge of the fundamental behavior of hydrogen and graphene in collisional conditions is essential for modeling the sputtering mechanism. The hydrogen adsorption rate is found to be dependent on the incident hydrogen energy and not on graphene temperature. Rather than destroying the graphene, hydrogen incidence at energies of less than 100 eV can be classified into three regimes of adsorption, reflection and penetration through one or more graphene layers. Incidence at the lowest energies is shown to distort the graphene structure.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Nakamura, H. Takayama, A. and Ito, A. 2008. Molecular Dynamics Simulation of Hydrogen Isotope Injection into Graphene. Contributions to Plasma Physics, Vol. 48, Issue. 1-3, p. 265.

Ito, Atsushi and Nakamura, Hiroaki 2008. Erosion of Graphene in Hydrogen Atom Gas. Japanese Journal of Applied Physics, Vol. 47, Issue. 6R, p. 4715.

Ito, Atsushi and Nakamura, Hiroaki 2008. Hydrogen isotope sputtering of graphite by molecular dynamics simulation. Thin Solid Films, Vol. 516, Issue. 19, p. 6553.

Ito, Atsushi Nakamura, Hiroaki and Takayama, Arimichi 2008. Molecular Dynamics Simulation of the Chemical Interaction between Hydrogen Atom and Graphene. Journal of the Physical Society of Japan, Vol. 77, Issue. 11, p. 114602.

Ohya, K. Kikuhara, Y. Inai, K. Kirschner, A. Borodin, D. Ito, A. Nakamura, H. and Tanabe, T. 2009. Simulation of hydrocarbon reflection from carbon and tungsten surfaces and its impact on codeposition patterns on plasma facing components. Journal of Nuclear Materials, Vol. 390-391, Issue. , p. 72.

Ito, Atsushi Wang, Ying Irle, Stephan Morokuma, Keiji and Nakamura, Hiroaki 2009. Molecular dynamics simulation of hydrogen atom sputtering on the surface of graphite with defect and edge. Journal of Nuclear Materials, Vol. 390-391, Issue. , p. 183.

Ito, A. Ohya, K. Inai, K. and Nakamura, H. 2010. Dependency of Tritium Retention in Graphite on Temperature Control of Molecular Dynamics. Contributions to Plasma Physics, Vol. 50, Issue. 3-5, p. 464.

Sun, Jizhong Li, Shouyang Stirner, Thomas Chen, Junlin and Wang, Dezhen 2010. Molecular dynamics simulation of energy exchanges during hydrogen collision with graphite sheets. Journal of Applied Physics, Vol. 107, Issue. 11,

Nakamura, Hiroaki Ito, Atsushi M. Saito, Seiki Takayama, Arimichi Tamura, Yuichi Ohno, Noriyasu and Kajita, Shin 2011. Molecular Dynamics Simulation of Hydrogen Injection onto Diamond Surfaces. Japanese Journal of Applied Physics, Vol. 50, Issue. 1S1, p. 01AB04.

Saito, Seiki Ito, Atsushi M. Takayama, Arimichi Kenmotsu, Takahiro and Nakamura, Hiroaki 2011. Hybrid simulation between molecular dynamics and binary collision approximation codes for hydrogen injection into carbon materials. Journal of Nuclear Materials, Vol. 415, Issue. 1, p. S208.

SAITO, Seiki TAKAYAMA, Arimichi ITO, Atsushi M. KENMOTSU, Takahiro and NAKAMURA, Hiroaki 2011. How to Combine Binary Collision Approximation and Multi-Body Potential for Molecular Dynamics. Progress in Nuclear Science and Technology, Vol. 2, Issue. 0, p. 44.

Saito, Seiki Ito, Atsushi M. and Nakamura, Hiroaki 2011. Reaction between graphene and hydrogen under oblique injection. Journal of Applied Physics, Vol. 110, Issue. 8,

Ohya, Kaoru 2011. Progress in modeling erosion and redeposition on plasma facing materials. Journal of Nuclear Materials, Vol. 415, Issue. 1, p. S10.

Fallet, Marcel and Stuart, Steven J. 2011. Evolution of carbon based surfaces under bombardment: Examining the steady-state surface properties and the effect of potential. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, Vol. 269, Issue. 11, p. 1271.

Ohya, K. Inai, K. Kikuhara, Y. Mohara, N. Ito, A. Nakamura, H. and Tanabe, T. 2011. Molecular dynamics study on hydrocarbon interaction with plasma facing walls. Journal of Nuclear Materials, Vol. 417, Issue. 1-3, p. 637.

Zhang Zhi-Hai Sun Ji-Zhong Liu Sheng-Guang and Wang De-Zhen 2012. Molecular dynamics simulation of energy exchanges between single hydrogen and graphite(001). Acta Physica Sinica, Vol. 61, Issue. 4, p. 047901.

Sun Ji-Zhong Zhang Zhi-Hai Liu Sheng-Guang and Wang De-Zhen 2012. Molecular dynamics simulation of energetic hydrogen isotopes bombarding the crystalline graphite(001). Acta Physica Sinica, Vol. 61, Issue. 5, p. 055201.

Saito, Seiki Ito, Atsushi M. Takayama, Arimichi and Nakamura, Hiroaki 2012. Anisotropic Bond Orientation of Amorphous Carbon by Deposition. Japanese Journal of Applied Physics, Vol. 51, Issue. 1S, p. 01AC05.

Wang, Ying Qian, Hu-Jun Morokuma, Keiji and Irle, Stephan 2012. Coupled Cluster and Density Functional Theory Calculations of Atomic Hydrogen Chemisorption on Pyrene and Coronene as Model Systems for Graphene Hydrogenation. The Journal of Physical Chemistry A, Vol. 116, Issue. 26, p. 7154.

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Molecular dynamics simulation of collisions between hydrogen and graphite

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