Derivation of potential model for LiAlO2 by simple and effective optimization of model parameters

“…1. We adopted a pairwise potential model [13] for simplicity, with reliance on high ionicity of LiAlO 2 . As mentioned below, the potential model shows good performance about the formation energies of Frenkel pairs and the melting point, which are material properties important for a displacement cascade simulation.…”

“…The Coulombic term was evaluated using the smoothed particle mesh Ewald method (SPME) [14], but the remaining terms were calculated directly with the cut-off distance of 10 Å. In our previous study [13], N 0 , N, and a n were determined to reproduce potential energies evaluated with planewave pseudopotential density functional theory (DFT) in various distorted crystal structures. In consequence, these parameters were obtained as N 0 = 4, N = 6 and a n listed in Ref.…”

“…In consequence, these parameters were obtained as N 0 = 4, N = 6 and a n listed in Ref. [13]. The effective charge of each ion was derived, respectively, from Mulliken population analysis as +0.7e for Li + , À1.1e for O 2À , and +1.5e for Al 3+ .…”

“…See Ref. [13] for more details. For a displacement cascade simulation, the potential model that is used must be able to address point defects.…”

“…For a displacement cascade simulation, the potential model that is used must be able to address point defects. The formation energy of a Li Frenkel pair (a pair of a vacancy and an interstitial of a certain element) was evaluated, respectively, as 2.92 eV by DFT calculation and as 3.07 eV using this potential model [13]. In addition, the formation energies of an O Frenkel pair and an Al Frenkel pair were obtained with the potential model as 6.20 eV and 6.60 eV, respectively.…”

Displacement cascade simulation of LiAlO2 using molecular dynamics

“…1. We adopted a pairwise potential model [13] for simplicity, with reliance on high ionicity of LiAlO 2 . As mentioned below, the potential model shows good performance about the formation energies of Frenkel pairs and the melting point, which are material properties important for a displacement cascade simulation.…”

“…The Coulombic term was evaluated using the smoothed particle mesh Ewald method (SPME) [14], but the remaining terms were calculated directly with the cut-off distance of 10 Å. In our previous study [13], N 0 , N, and a n were determined to reproduce potential energies evaluated with planewave pseudopotential density functional theory (DFT) in various distorted crystal structures. In consequence, these parameters were obtained as N 0 = 4, N = 6 and a n listed in Ref.…”

“…In consequence, these parameters were obtained as N 0 = 4, N = 6 and a n listed in Ref. [13]. The effective charge of each ion was derived, respectively, from Mulliken population analysis as +0.7e for Li + , À1.1e for O 2À , and +1.5e for Al 3+ .…”

“…See Ref. [13] for more details. For a displacement cascade simulation, the potential model that is used must be able to address point defects.…”

“…For a displacement cascade simulation, the potential model that is used must be able to address point defects. The formation energy of a Li Frenkel pair (a pair of a vacancy and an interstitial of a certain element) was evaluated, respectively, as 2.92 eV by DFT calculation and as 3.07 eV using this potential model [13]. In addition, the formation energies of an O Frenkel pair and an Al Frenkel pair were obtained with the potential model as 6.20 eV and 6.60 eV, respectively.…”

Displacement cascade simulation of LiAlO2 using molecular dynamics

Optical properties of oxygen vacancy in gamma-LiAlO2: A computational study

Modeling of influence of lithium vacancy on thermal conductivity in lithium aluminate