Transition metals and transition metal compounds are important to catalysis, photochemistry, and many superconducting systems. We study the performance of diffusion Monte Carlo (DMC) applied to transition metal containing dimers (TMCDs) using single-determinant Slater–Jastrow trial wavefunctions and investigate the possible influence of the locality and pseudopotential errors. We find that the locality approximation can introduce nonsystematic errors of up to several tens of kilocalories per mole in the absolute energy of Cu and CuH if Ar or Mg core pseudopotentials (PPs) are used for the 3d transition metal atoms. Even for energy differences such as binding energies, errors due to the locality approximation can be problematic if chemical a...
Accurately predicting the formation energy of a compound, which describes its thermodynamic stabilit...
Diffusion Monte Carlo methods can give highly accurate results for correlated systems, provided that...
Achieving both bond dissociation energies (BDEs) and their trends for the R–X bonds with R = Me, Et,...
For the first time, quantum Monte Carlo orbital optimization of multi-configuration wave functions f...
Performance of the fixed-node diffusion quantum Monte Carlo method (FN-DMC) with a single Slater-Jas...
Fixed-node diffusion Monte Carlo (FNDMC) simulations are one of the most promising methods for descr...
Computer simulation plays a central role in modern-day materials science. The utility of a given com...
Accurate first-principles calculations can provide valuable predictions for material-specific proper...
The bond dissociation energies of a set of 44 3d transition metal-containing diatomics are computed ...
We present accurate nonrelativistic ground-state energies of the transition metal atoms of the 3d se...
With the development of peta-scale computers and exa-scale only a few years away, the quantum Monte ...
International audienceWe study beryllium dihydride (BeH 2) and acetylene (C 2 H 2) molecules using r...
Calculation of Transition-Metal Systems with Diffusion Monte CarloThe diffusion quantum Monte Carlo ...
Diffusion Monte Carlo (DMC) is a technique for obtaining the ground-state solution to the vibrationa...
In this work, we report potential energy surfaces (PESs) of the sodium dimer calculated by variation...
Accurately predicting the formation energy of a compound, which describes its thermodynamic stabilit...
Diffusion Monte Carlo methods can give highly accurate results for correlated systems, provided that...
Achieving both bond dissociation energies (BDEs) and their trends for the R–X bonds with R = Me, Et,...
For the first time, quantum Monte Carlo orbital optimization of multi-configuration wave functions f...
Performance of the fixed-node diffusion quantum Monte Carlo method (FN-DMC) with a single Slater-Jas...
Fixed-node diffusion Monte Carlo (FNDMC) simulations are one of the most promising methods for descr...
Computer simulation plays a central role in modern-day materials science. The utility of a given com...
Accurate first-principles calculations can provide valuable predictions for material-specific proper...
The bond dissociation energies of a set of 44 3d transition metal-containing diatomics are computed ...
We present accurate nonrelativistic ground-state energies of the transition metal atoms of the 3d se...
With the development of peta-scale computers and exa-scale only a few years away, the quantum Monte ...
International audienceWe study beryllium dihydride (BeH 2) and acetylene (C 2 H 2) molecules using r...
Calculation of Transition-Metal Systems with Diffusion Monte CarloThe diffusion quantum Monte Carlo ...
Diffusion Monte Carlo (DMC) is a technique for obtaining the ground-state solution to the vibrationa...
In this work, we report potential energy surfaces (PESs) of the sodium dimer calculated by variation...
Accurately predicting the formation energy of a compound, which describes its thermodynamic stabilit...
Diffusion Monte Carlo methods can give highly accurate results for correlated systems, provided that...
Achieving both bond dissociation energies (BDEs) and their trends for the R–X bonds with R = Me, Et,...