Refinement of Crystallographic Parameters in Refractory Metal Disilicides

K. Tanaka; K. Nawata; H. Inui; M. Yamaguchi; M. Koiwa

doi:10.1557/PROC-646-N4.3.1

Abstract

The crystallographic structures of seven refractory metal (Ti, V, Cr, Nb, Mo, Ta and W) disilicides with the C11b, C40 and C54 structures have been refined through analysis of single-crystal X-ray diffraction data. Crystallographic parameters refined are lattice constants, atomic parameters and the space group of the C40 disilicides. In most of previous studies, silicon atoms have been considered to locate at the ideal positions so that the refractory metal atoms are perfectly six-fold coordinated in RSi2 layers prevailing in all the three structures. The present analysis shows that the silicon atoms are displaced from the ideal positions. The magnitude of such displacement is found to be closely related to the interatomic distance in these pseudo-hexagonally arranged RSi2 layers. The space group of three of the four C40 disilicides, VSi2, CrSi2 and TaSi2, is determined to be P6422, which is of chirality with respect to that (P6222) assigned in the previous studies.

References

REFERENCES

1. Vasudevan, A. K. and Petrovic, J. J., Mater. Sci. Eng. A, 155, 1 (1992).Google Scholar

2. Ito, K., Inui, H., Shirai, Y. and Yamaguchi, M., Phil. Mag. A, 72, 1075 (1995).Google Scholar

3. Nava, F., Tu, K. N., Thomas, O., Senateur, J. P., Madar, R., Borghesi, A., Guizzetti, G., Gottlieb, U., Laborde, O. and Bisi, O., Sci. Rep., 9, 141 (1993).Google Scholar

4. Murarka, S. P., Intermetallics, 3, 173 (1995).Google Scholar

5. Villars, P. and Calvert, L. D., Pearson's Handbook of Crystallographic Data for Intermetallic Phases, (American Society for Metal, 1985).Google Scholar

6. Bhattacharyya, B. K., Bylander, D. M. and Kleinman, L., Phys. Rev. B, 32, 7973 (1985).Google Scholar

7. Alouani, M. and Albers, R. C., Phys. Rev. B, 43, 6500 (1991).Google Scholar

8. Mattheiss, L. F., Phys. Rev. B, 45, 3252 (1992).Google Scholar

9. Harada, Y., Morinaga, M., Saso, D., Takata, M. and Sakata, M., Intermetallics, 6, 523 (1998).Google Scholar

10. Kubiak, R., Horyn, R., Broda, H. and Lukaszewicz, K., Bulletin de L'academie Polonaise des Sciences Serie des Sciences Chimiques, 20, 429 (1972).Google Scholar

11. Jeitschko, W., Acta Cryst. B, 33, 2347 (1977).Google Scholar

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Yan, Wanjun Zhou, Shiyun Xie, Quan Zhang, Chunhong and Zhang, Zhongzheng 2011. First principle investigation of CrSi2 with doping V. p. 1747.

Yamada, Takahiro and Yamane, Hisanori 2011. Crystal structure and thermoelectric properties of β-MoSi2. Intermetallics, Vol. 19, Issue. 7, p. 908.

Villars, P. Cenzual, K. Daams, J. Gladyshevskii, R. Shcherban, O. Dubenskyy, V. Kuprysyuk, V. Savysyuk, I. and Zaremba, R. 2011. Structure Types. Part 10: Space Groups (140) I4/mcm – (136) P42/mnm. Vol. 43A10, Issue. , p. 183.

Blatov, Vladislav A. 2011. Inorganic 3D Structures. p. 31.

Morito, Haruhiko Karahashi, Taiki Uchikoshi, Masahito Isshiki, Minoru and Yamane, Hisanori 2012. Low-Temperature Purification of Silicon by Dissolution and Solution Growth in Sodium Solvent. Silicon, Vol. 4, Issue. 2, p. 121.

Yamane, Hisanori Sato, Hiroto and Yamada, Takahiro 2012. Powder X-ray diffraction pattern of NbSi1.9 containing planar stacking faults. Intermetallics, Vol. 22, Issue. , p. 189.

Karuppaiah, S. Beaudhuin, M. and Viennois, R. 2013. Investigation on the thermoelectric properties of nanostructured. Journal of Solid State Chemistry, Vol. 199, Issue. , p. 90.

Ahamad Mohiddon, Md. Lakshun Naidu, K. Ghanashyam Krishna, M. Dalba, G. Ahmed, S. I. and Rocca, F. 2014. Chromium oxide as a metal diffusion barrier layer: An x-ray absorption fine structure spectroscopy study. Journal of Applied Physics, Vol. 115, Issue. 4,

Schouwink, Pascal Smrčok, Ľubomír and Černý, Radovan 2014. Role of the Li+node in the Li-BH4substructure of double-cation tetrahydroborates. Acta Crystallographica Section B Structural Science, Crystal Engineering and Materials, Vol. 70, Issue. 5, p. 871.

McGlone, John M. Olsen†, Kristopher R. Stickle, William F. Abbott, James E. Pugliese, Roberto A. Long, Greg S. Keszler, Douglas A. and Wager, John F. 2017. TaWSi amorphous metal thin films: composition tuning to improve thermal stability. MRS Communications, Vol. 7, Issue. 3, p. 715.

Zhang, Yingyi Zhao, Jie Li, Jinghui Lei, Jie and Cheng, Xiangkui 2019. Effect of hot-dip siliconizing time on phase composition and microstructure of Mo–MoSi2 high temperature structural materials. Ceramics International, Vol. 45, Issue. 5, p. 5588.

Jiang, Liwu Wu, Meiling Shi, Peng and Zhang, Chuanhui 2019. The effect of Al and Cr elements on the oxidation resistance of MoSi2 via first-principles calculation. Progress in Natural Science: Materials International, Vol. 29, Issue. 1, p. 65.

Xiong, Huihui Gan, Lei and Li, Mingzhou 2020. Improving the oxidation resistance of WSi2 by boron doping: A DFT study. Materials Today Communications, Vol. 25, Issue. , p. 101312.

Likhanov, Maxim S. Sytov, Nikita V. Wei, Zheng Dikarev, Evgeny V. and Shevelkov, Andrei V. 2020. Nowotny Chimney Ladder Phases with Group 5 Metals: Crystal and Electronic Structure and Relations to the CrSi2 Structure Type. Crystals, Vol. 10, Issue. 8, p. 670.

Dong, Zhuoya and Ma, Yanhang 2020. Atomic-level handedness determination of chiral crystals using aberration-corrected scanning transmission electron microscopy. Nature Communications, Vol. 11, Issue. 1,

Solomkin, F. Yu. Samunin, A. Yu. Zaitseva, N. V. Sharenkova, N. V. Isachenko, G. N. Samusevich, K. L. Klechkovskaya, V. V. Orekhov, A. S. Rakova, E. V. and Drozdova, E. V. 2021. Feasibility of Using Chromium as a Switching Material for CrSi2. Journal of Surface Investigation: X-ray, Synchrotron and Neutron Techniques, Vol. 15, Issue. 4, p. 678.

Pavlosiuk, Orest Swatek, Przemysław Wojciech Wang, Jian-Ping Wiśniewski, Piotr and Kaczorowski, Dariusz 2022. Giant magnetoresistance, Fermi-surface topology, Shoenberg effect, and vanishing quantum oscillations in the type-II Dirac semimetal candidates MoSi2 and WSi2. Physical Review B, Vol. 105, Issue. 7,

Suvorova, E. I. Solomkin, F. Yu. Arkharova, N. A. Sharenkova, N. V. and Isachenko, G. N. 2023. Microstructure and Phase Composition of an Alloy of Iron and Chrome Disilicides. Semiconductors, Vol. 57, Issue. 2, p. 143.

Suvorova, Elena I. Arkharova, Natalya A. Ivanova, Anna G. Solomkin, Fedor Yu. and Buffat, Philippe A. 2023. Phases and Interfaces in the Cr–Fe–Si Ternary System: X-ray Diffraction and Electron Microscopy Study. Inorganics, Vol. 11, Issue. 2, p. 73.

Lukasov, M. S. Arkharova, N. A. Orekhov, A. S. Rakova, E. V. Solomkin, F. Yu. and Klechkovskaya, V. V. 2023. Microstructure of a CrSi2 Transition Layer Produced by Hot Pressing of Cr and Si. Crystallography Reports, Vol. 68, Issue. 4, p. 615.

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Refinement of Crystallographic Parameters in Refractory Metal Disilicides

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

Article contents

Refinement of Crystallographic Parameters in Refractory Metal Disilicides

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