First-principles estimation of partition functions representing disordered lattices such as the cubic phases of Li2OHCl and Li2OHBr

Abstract: In order to develop computational methods that can simulate thermodynamic properties of disordered materials at a first principles level, we investigate the use of a random set of configurations to evaluate the canonical partition function of lattice-based disordered systems. Testing the sampling method on the one and two dimensional Ising models indicates that for the ordered system at low temperature, convergence is achieved when the number of samples S is comparable or larger than the number of configuratio… Show more

“…1(a) . Table 1 lists the optimized lattice parameters of Li 2 OHBr obtained by DFT calculations, together with the data from Howard et al 19 The lattice parameters are a = 8.015 Å, b = 8.152 Å, and c = 7.944 Å, which are agree with the experiment data (within 2% error). To obtain the electronic properties of Li 2 OHBr, the electronic band structure of Li 2 OHBr is evaluated.…”

Theoretical insights into interfacial stability and ionic transport of Li₂OHBr solid electrolyte for all-solid-state batteries

“…1(a) . Table 1 lists the optimized lattice parameters of Li 2 OHBr obtained by DFT calculations, together with the data from Howard et al 19 The lattice parameters are a = 8.015 Å, b = 8.152 Å, and c = 7.944 Å, which are agree with the experiment data (within 2% error). To obtain the electronic properties of Li 2 OHBr, the electronic band structure of Li 2 OHBr is evaluated.…”

Theoretical insights into interfacial stability and ionic transport of Li₂OHBr solid electrolyte for all-solid-state batteries

“…8 and 16) while cooling Li 2 OHBr below −50 °C results in the transition to orthorhombic. 41 Anion substitution (Br for Cl) tunes the lattice parameter and improves the cubic stability. DFT supports this by showing that the Li–halide distances decrease.…”

“…63) as the starting configuration because this structure is reported to have the lowest energy from 0 to 300 K for the Li 2 OHX (X = Cl, Br) systems. 41 We compared the simulated XRD based on the optimized structure models with the experimental data to confirm the mixed halides' crystal structure. pLiAP phonon densities of states were calculated using density functional perturbation theory (DFPT) based on the optimized geometries.…”

“…S4 †), respectively, as expected given their Goldschmidt tolerance factors. 41 The orthorhombic phase can be considered a distortion of the Li sublattice with unequal Li + anions distances, contrary to an ideal cubic structure. For example, in the orthorhombic Li 2 OHCl the Li-Cl lengths span from 2.664 to 2.785 Å, with a $4.5% difference.…”

Halide sublattice dynamics drive Li-ion transport in antiperovskites

“…In the search for fillers that can improve the PEO-based polymer electrolytes at low cost, we discovered lithium-rich anti-perovskite (LiRAP) Li 2 OHBr to be a strong candidate. − The idea of developing LiRAP as fillers was inspired by our previous work, in which LiRAP with high stability to lithium metal and high lithium ion conductivity was used as a protective layer between lithium metal and electrolytes to regulate lithium plating/stripping . Compared with metal oxide fillers (e.g., Al 2 O 3 or SiO 2 ) without the lithium ion conductivity property, Li 2 OHBr as a superionic conductor processes large amounts of mobile lithium ions in the crystal lattice and a low energy barrier for lithium ion transport, and therefore there is a high lithium ion conductivity. − In fact, Li 2 OHBr features easy processing and low cost and environmental impact and can be more readily adopted for practical application. Herein, Li 2 OHBr-containing PEO polymer electrolytes were facilely prepared by a mixture in solution followed by solvent evaporation.…”

Lithium-Rich Anti-perovskite Li₂OHBr-Based Polymer Electrolytes Enabling an Improved Interfacial Stability with a Three-Dimensional-Structured Lithium Metal Anode in All-Solid-State Batteries