Adsorption and diffusion of atoms 1, 2 and 13 groups on the surface of antimony telluride | Izvestiya vuzov. Fizika. 2019. № 3. DOI: 10.17223/00213411/62/3/110

Adsorption and diffusion of atoms 1, 2 and 13 groups on the surface of antimony telluride

In this work we represent results of first-principles calculations for adsorption and diffusion of adatoms 1, 2 and 13 groups on topological insulator Sb₂Te₃surface (0001). It is shown that most of investigated atoms has a minimum of energy in FCC hollow sites. The exception is beryllium, boron, indium and thallium, for them HCP hollow sites are preferable. Diffusion of adatoms on surface (0001) Sb₂Te₃proceeds as two-stage mechanism, that includes hop from FCC to HCP hollow sites then from HCP to FCC hollow sites. For beryllium, boron, indium and thallium atoms the order of the hops is shifted because for these atoms FCC hollow sites are preferable energetically. The energy barriers of hop on the surface and attempt frequencies are found based on which diffusion lengths are calculated analytically. The temperatures of the diffusion activation, at which atom covers one interatomic distance (2.5 Å) per minute, are determined. It is revealed that the highest activation temperature (165 K) corresponds to beryllium, and the lowest (39 K) - cesium.

Download file

Counter downloads: 103

Keywords

charge transfer, diffusion, adsorption, density functional method, topological isolator, перенос заряда, диффузия, адсорбция, метод функционала электронной плотности, топологический изолятор

Authors

Name	Organization	E-mail
Ryabishchenkova A.G.	National Research Tomsk State University	ryaange@gmail.com
Kuznetsov V.M.	National Research Tomsk State University	kuznetsov@rec.tsu.ru

Всего: 2

References

Gosalves M.A., Otrokov M.M., Ferrando N., et al. // Phys. Rev. B. - 2016. - V. 93. - P. 075429.

Sahin H. and Peeters F.M. // Phys. Rev. B. - 2013. - V. 87. - P. 085423.

Bader R.F.W. Encyclopedia of Computational Chemistry. - John Wiley & Sons, Ltd, 2002.

Jonsson H., Mills G. and Jacobsen K.W. // Classical and Quantum Dynamics in Condensed Phase Simulations. - World Scientific, 1998. - 385 p.

Metz W. and Hohlwein D. // Carbon. - 1975. - V. 13. - No. 1. - P. 84.

Kresse G. and Furthmüller J. // Phys. Rev. B. - 1996. - V. 54. - P. 11169.

Kresse G. and Joubert D. // Phys. Rev. B. - 1999. - V. 59. - P. 1758.

Loptien P., Zhou L., Wiebe J., et al. // Phys. Rev. B. - 2014. - V. 89. - P. 085401.

Bianchi M., Hatch R.C., Li Z., et al. // ACS Nano. - 2012. - V. 6. - No. 8. - P. 7009-7015.

Zhu Z.-H., Levy G., Ludbrook B., et al. // Phys. Rev. Lett. - 2011. - V. 107. - P. 186405.

Рябищенкова А.Г., Отроков М.М., Кузнецов В.М., Чулков Е.В. // ЖЭТФ. - 2015. - Т. 148. - Вып. 3(9). - С. 535-548.

Seibel C., Maab H., Ohtaka M., et al. // Phys. Rev. B. - 2012. - V. 86. - No. 23. - P. 235105.

Roy S., Meyerheim H.L., Ernst A., et al. // Phys. Rev. Lett. - 2014. - V. 113. - P. 116802.

Hasan M. and Kane C. // Rev. Mod. Phys. - 2010. - No. 82. - P. 3045.

Pauly C., Bihlmayer G., Liebmann M., et al. // Phys. Rev. B. - 2012. - V. 86. - No. 23. - P. 235106.