BIMEVOX had the potential to play an important role in solid oxide fuel cell, especially as the electrolyte due to their high ionic conductivity. In this work, oxide ion migrations of γ-Bi₂VO_5.5 and BIMEVOX were simulated using density function theory (DFT), Mott-Littleton method, and molecular dynamic simulation. In γ-Bi₂VO_5.5, there were oxygen vacancies at the equatorial position in the vanadate layers. These vacancies could facilitate oxide ions migration. The Enthalpy of the oxide migration for γ-Bi₂VO_5.5 based on DFT calculation was 0.38 eV, which was in a good agreement with experimental results. The γ-Bi₂VO_5.5 can be stabilized by partial substitution of V⁵⁺ with Cu²⁺, Ga³⁺, and Ta⁵⁺. Defect simulation results using the Mott-Littleton method showed that the total maximum energies of region II were achieved at concentrations of 10, 10, and 20%, respectively for Cu²⁺, Ga³⁺, and Ta⁵⁺. The calculated concentration of Cu²⁺, Ga³⁺, and Ta⁵⁺ were in a good agreement with those of experiment results, where the highest ionic conductivity obtained. The results of the molecular dynamics simulation showed that the activation energies of oxide ion migration in γ-Bi₂VO_5.5 and BIMEVOX (ME = Cu and Ta) respectively were 0.19, 0.21, and 0.10 eV, close to experimental values.

[1] Cho, H.S., Sakai, G., Shimanoe, K., and Yamazoe, N., 2005, Preparation of BiMeVOx (Me= Cu, Ti, Zr, Nb, Ta) compounds as solid electrolyte and behavior of their oxygen concentration cells, Sens. Actuators, B, 109 (2), 307–314.

[2] Chmielowiec, J., Paściak, G., and Bujło, P., 2008, Ionic conductivity and thermodynamic stability of La-doped BIMEVOX, J. Alloys Compd., 451 (1-2), 676–678.

[3] Khaerudini, D.S., Guan, G., Zhang, P., Hao, X., and Abudula, A., 2014, Prospects of oxide ionic conductivity bismuth vanadate-based solid electrolytes, Rev. Chem. Eng., 30 (6), 539–551.

[4] Tripathy, D., Saikia, A., and Pandey, A.C., 2019, Effect of simultaneous Ti and Nb doping on structure and ionic conductivity of Bi₂V₁−_xTi_x/2Nb_x/₂O_5.5−δ (0.1≤ x≤ 0.25) ceramics, Ionics, 25 (5), 2221–2230.

[5] Tripathy, D., and Pandey, A., 2018, Structural and impedance studies of Ti^IV and Nb^V co-doped bismuth vanadate system, J. Alloys Compd., 737, 136–143.

[6] Pernot, E., Anne, M., Bacmann, M., Strobel, P., Fouletier, J., Vannier, R.N., Mairesse, V.G., Abraham, F., and Nowogrocki, G., 1994, Structure and conductivity of Cu and Ni-substituted Bi₄V₂O₁₁ compounds, Solid State Ionics, 70-71, 259–263.

[7] Abrahams, I., Krok, F., Malys, M., and Bush, A.J., 2001, Defect structure and ionic conductivity as a function of thermal history in BIMGVOX solid electrolytes, J. Mater. Sci., 36 (5), 1099–1104.

[8] Rusli, R., Abrahams, I., Patah, A., Prijamboedi, B., and Ismunandar, 2014, Ionic conductivity of Bi₂Ni_xV_1−xO_5.5−3x/2 (0.1 ≤ x ≤ 0.2) oxides prepared by a low temperature sol-gel route, AIP Conf. Proc., 1589 (1), 178.

[9] Abraham, F., Boivin, J.C., Mairesse, G., and Nowogrocki, G., 1990, The BIMEVOX series: A new family of high performances oxide ion conductors, Solid State Ionics, 40-41, 934–937.

[10] Abrahams, I., and Krok, F., 2002, Defect chemistry of the BIMEVOXes, J. Mater. Chem., 12 (12), 3351–3362.

[11] Khaerudini, D.S., Guan, G., Zhang, P., Hao, X., Kasai, Y., Kusakabe, K., and Abudula, A., 2014, Structural and conductivity characteristics of Bi₄Mg_xV_2−xO_11−δ (0⩽ x ⩽ 0.3) as solid electrolyte for intermediate temperature SOFC application, J. Alloys Compd., 589, 29–36.

[12] Kant, R., Singh, K., and Pandey, O.P., 2010, Structural, thermal and transport properties of Bi₄V_{2_x}Ga_xO_{11_δ} (0 ≤ x ≤ 0.4), Ionics, 16 (3), 277–282.

[13] Dereeper, E., Briois, P., and Billard, A., 2017, BITAVOX coatings obtained by reactive magnetron sputtering: Influence of thickness and composition, Solid State Ionics, 304, 7–12.

[14] Kant, R., Singh, K., and Pandey, O.P., 2008, Synthesis and characterization of bismuth vanadate electrolyte material with aluminium doping for SOFC application, Int. J. Hydrogen Energy, 33 (1), 455–462.

[15] Krok, F., Abrahams, I., Zadrożna, A., Małys, M., Bogusz, W., Nelstrop, J.A.G., and Bush, A.J., 1999, Electrical conductivity and structure correlation in BIZNVOX, Solid State Ionics, 119 (1-4), 139–144.

[16] Mairesse, G., 1999, Advances in oxygen pumping concept with BIMEVOX, C. R. Acad. Sci. IIC: Chim., 2 (11-13), 651–660.

[17] Mairesse, G., Roussel, P., Vannier, R.N., Anne, M., Pirovano, C., and Nowogrocki, G.L., 2003, Crystal structure determination of α, β and γ-Bi₄V₂O₁₁ polymorphs. Part I: γ and β-Bi₄V₂O₁₁, Solid State Sci., 5 (6), 851–859.

[18] Payne M.C., and TCM group in Cambridge, 2005, CASTEP of Material Studio Modeling from Accerys, series number 3.2.00, with consumer is Politecnico di Torino.

[19] Gale, J.D., 1997, GULP: A computer program for the symmetry-adapted simulation of solids, J. Chem. Soc., Faraday Trans., 93 (4), 629-637.

[20] Todorov, I.T., Smith, W., Trachenko, K., and Dove, M.T., 2006, DL_POLY_3: new dimensions in molecular dynamics simulations via massive parallelism, J. Mater. Chem., 16 (20), 1911–1918.

[21] Voronkova, V.I., Yanovskii, V.K., Kharitonova, E.P., and Rudnitskaya, O.G., 2005, Superionic conductors in the Bi₂WO₆-Bi₂VO_5.5 system, Inorg. Mater., 41 (7), 760–765.

[22] Kant, R., Singh, K., and Pandey, O.P., 2009, Microstructural and electrical behavior of Bi₄V_2-xCu_xO_11-δ (0 ≤ x ≤ 0.4), Ceram. Int., 35 (1), 221–227.

[23] Lazure, S., Vernochet, C., Vannier, R.N., Nowogrocki, G., and Mairesse, G., 1996, Composition dependence of oxide anion conduction in the BIMEVOX family, Solid State Ionics, 90 (1-4), 117–123.

[24] Murasheva, V.V., Fortalnova, E.A., Politova, E.A., Politova, E.D., Safronenko, M.G., Stefanovich, S.Y., and Venskovskii, N.U., 2008, Phase transitions in the BIMEVOX solid solutions with Me = Ga, Zr, Mater. Sci. Forum, 587-588, 114–117.

[25] Joubert, O., Jouanneaux, A., Ganne, M., Vannier, R.N., and Mairesse, G., 1994, Solid phase synthesis and characterization of new BIMEVOX series: Bi₄V_2−xM_xO₁₁ (M = Sb^v, Nb^v), Solid State Ionics, 73 (3-4), 309–318.

[26] Ramsahye, N.A., and Bell, R.G., 2005, Cation mobility and the sorption of chloroform in zeolite NaY: Molecular dynamics study, J. Phys. Chem. B, 109 (10), 4738–4747.

[27] Guillodo, M., Bassat, J.M., Fouletier, J., Dessemond, L., and Del Gallo, P., 2003, Oxygen diffusion coefficient and oxygen exchange coefficient of BIMEVOX.10 (ME = Cu, Co) ceramic membranes, Solid State Ionics, 164 (1-2), 87–96.

[28] Krok, F., Bogusz, W., Kurek, P., Wasiucionek, M., Jakubowski, W., and Dygas, J., 1993, Influence of preparation procedure on some physical properties of BICUVOX, Mater. Sci. Eng., B, 21 (1), 70–76.

[29] Simner, S.P., Suarez‐Sandoval, D., Mackenzie, J.D., and Dunn, B., 1997, Synthesis, densification, and conductivity characteristics of BICUVOX oxygen‐ion‐conducting ceramics, J. Am. Ceram. Soc., 80 (10), 2563–2568.