Development of Density-Functional Tight-Binding Parameters for the Molecular Dynamics Simulation of Zirconia, Yttria, and Yttria-Stabilized Zirconia

Abstract: In this work, a set of density-functional tight-binding (DFTB) parameters for the Zr−Zr, Zr−O, Y−Y, Y−O, and Zr− Y interactions was developed for bulk and surface simulations of ZrO 2 (zirconia), Y 2 O 3 (yttria), and yttria-stabilized zirconia (YSZ) materials. The parameterization lays the ground work for realistic simulations of zirconia-, yttria-, and YSZ-based electrolytes in solid oxide fuel cells and YSZ-based catalysts on long timescales and relevant size scales. The parameterization was validated for t… Show more

“…To improve the present results within DFT accuracy, one of the few possible options is to move to the density functional-based tight binding method, which is based on a second-order expansion of the Kohn–Sham total energy with respect to charge density fluctuations. 62 In order to investigate Majorana fermions, the SnTe NWs should host superconductivity beyond the topological properties demonstrated in the previous section. The superconductivity can be realized using the proximity effect 63 by doping 64 or interfacing SnTe with PbTe.…”

Density Functional Theory Study of the Spin–Orbit Insulating Phase in SnTe Cubic Nanowires: Implications for Topological Electronics

“…To improve the present results within DFT accuracy, one of the few possible options is to move to the density functional-based tight binding method, which is based on a second-order expansion of the Kohn–Sham total energy with respect to charge density fluctuations. 62 In order to investigate Majorana fermions, the SnTe NWs should host superconductivity beyond the topological properties demonstrated in the previous section. The superconductivity can be realized using the proximity effect 63 by doping 64 or interfacing SnTe with PbTe.…”

Density Functional Theory Study of the Spin–Orbit Insulating Phase in SnTe Cubic Nanowires: Implications for Topological Electronics

“…Lower panel: transition state of aldol addition through an X + −Enolate ∧ Keto mechanism over a reduced surface of CeO 2 (111), where an aldehyde and enolate each adsorbed at surface oxygen vacancy sites. molecular dynamics, 102 these simulation methods as well as kinetic Monte Carlo 103 methods will enable a more full understanding of what occurs on any given surface under a given set of conditions. Conclusions about the dominant reactive adsorbate species must be carefully interpreted to be condition dependent.…”

“…The age-old geometric vs electronic arguments tend to persist with this chemistry, and our abilities to identify the true underlying nature of the proposed chemistry are rapidly advancing with improved characterization and theory. As machine learning augmented electronic structure calculations increase in accuracy and advances are made in ab initio molecular dynamics, these simulation methods as well as kinetic Monte Carlo methods will enable a more full understanding of what occurs on any given surface under a given set of conditions. Conclusions about the dominant reactive adsorbate species must be carefully interpreted to be condition dependent.…”

Toward Understanding and Controlling Organic Reactions on Metal Oxide Catalysts

“…14,44,45 The applicability of the DFTB method requires the availability of parameter sets for all pairs of atoms present in the system. 46,47 This approach has been already tested on the 2D materials 48 and it was applied for defected Ti 2 CO 2 MXene. 14 However, when compared with the exact eigenstates and eigenvalues from the exact calculations in the finite Hubbard model, 49 the tight binding case is a rather crude approximation.…”

Prediction of induced magnetism in 2D Ti₂C based MXenes by manipulating the mixed surface functionalization and metal substitution computed by xTB model Hamiltonian of the DFTB method