MgNb 2 O 6 with a columbite structure was theoretically predicted as a prospective oxygen ion conductor. This compound was successfully synthesized by the Pechini method. The Li-and Cu-doped samples Mg 1−x M x Nb 2 O 6−δ (x = 0.1 and 0.2; M = Li and Cu) were prepared in the same way. The columbite structure (Sp.gr. Pbcn) was formed for the samples with x = 0 and x(Cu) = 0.1 and 0.2, while Li-doping led to the formation of two-phase ceramics with Mg 1−x Li x Nb 2 O 6−δ and LiNbO 3 components. The lithium and copper doping led to a decreasing sintering temperature by 100−200 °C down to ∼1050 °C. For Mg 1−x Li x Nb 2 O 6−δ (x = 0, 0.1, and 0.2), the experiments revealed pure oxygen ion conductivity of σ ∼10 −5 Scm −1 at 800 °C, an activation energy E a,σ of 0.86 eV, and good stability in a wide range of temperature, oxygen partial pressure, and in an atmosphere of carbon dioxide. For the Cu-doped samples, mixed n-type electronic and oxygen ion (T > 400 °C) conductivity was determined up to 2 × 10 −3 Scm −1 at 800 °C with E a,σ = 0.21 eV at x(Cu) = 0.2.
We
present the stepwise computer screening results to identify
solids prone to Zn2+-ion conductivity. The rapid geometrical–topological
(GT) screening based on Voronoi partition was utilized as the first
step for high-throughput analysis of the ICSD. We found that 334 of
782 Zn-/O-containing compounds possess one-dimensional (1D)-, two-dimensional
(2D)-, or three-dimensional (3D)-periodic Zn2+-ion migration
maps. Among them, 83 compounds were previously unknown as possible
Zn2+-ion conductors. We applied bond valence site energy
(BVSE) calculations to evaluate the migration energies for the Zn2+-ion conduction and to ensure that this migration barrier
was the lowest of all ions in the respective structure. Of the 83
compounds, 27 fulfilled the condition of being solely Zn2+ conductors. For the nine most promising compounds, we used the Nudged
Elastic Band (NEB) method within the density functional theory (DFT)
approach to verify Zn2+-ion conductivity. This yielded
the most interesting candidates (ZnM2O4, M =
Fe, Cr, V; ZnP2O6) with migration energies of
less than 0.7 eV/ion. Finally, we simulated ionic conductivities within
the kinetic Monte Carlo approach, compared the results of different
approaches, and commented on the complexity of the promising structures.
We conclude with the proposal of Zn-ion all-solid-state battery variants.
The list of the novel prospective Zn2+-ion conductors with
characteristics was uploaded to our database batterymaterials.info.
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