Your search keyword '"Kent, Paul R. C."' showing total 5 results

1. Force-free identification of minimum-energy pathways and transition states for stochastic electronic structure theories

Author

Iyer, Gopal R., Whelpley, Noah, Tiihonen, Juha, Kent, Paul R. C., Krogel, Jaron T., and Rubenstein, Brenda M.

Subjects

Physics - Chemical Physics, Quantum Physics

Abstract

Stochastic electronic structure theories, e.g., Quantum Monte Carlo methods, enable highly accurate total energy calculations which in principle can be used to construct highly accurate potential energy surfaces. However, their stochastic nature poses a challenge to the computation and use of forces and Hessians, which are typically required in algorithms for minimum-energy pathway (MEP) and transition state (TS) identification, such as the nudged-elastic band (NEB) algorithm and its climbing image formulation. Here, we present strategies that utilize the surrogate Hessian line-search method - previously developed for QMC structural optimization - to efficiently identify MEP and TS structures without requiring force calculations at the level of the stochastic electronic structure theory. By modifying the surrogate Hessian algorithm to operate in path-orthogonal subspaces and on saddle points, we show that it is possible to identify MEPs and TSs using a force-free QMC approach. We demonstrate these strategies via two examples, the inversion of the ammonia molecule and an SN2 reaction. We validate our results using Density Functional Theory- and coupled cluster-based NEB calculations. We then introduce a hybrid DFT-QMC approach to compute thermodynamic and kinetic quantities - free energy differences, rate constants, and equilibrium constants - that incorporates stochastically-optimized structures and their energies, and show that this scheme improves upon DFT accuracy. Our methods generalize straightforwardly to other systems and other high-accuracy theories that similarly face challenges computing energy gradients, paving the way for highly accurate PES mapping, transition state determination, and thermodynamic and kinetic calculations, at significantly reduced computational expense.

Published

2024

2. Towards a Systematic Improvement of the Fixed-Node Approximation in Diffusion Monte Carlo for Solids -- A Case Study In Diamond

Author

Benali, Anouar, Gasperich, Kevin, Jordan, Kenneth D., Applencourt, Thomas, Luo, Ye, Bennett, M. Chandler, Krogel, Jaron T., Shulenburger, Luke, Kent, Paul R. C., Loos, Pierre-François, Scemama, Anthony, and Caffarel, Michel

Subjects

Physics - Chemical Physics, Condensed Matter - Materials Science

Abstract

While Diffusion Monte Carlo (DMC) is in principle an exact stochastic method for \textit{ab initio} electronic structure calculations, in practice the fermionic sign problem necessitates the use of the fixed-node approximation and trial wavefunctions with approximate nodes (or zeros) must be used. This approximation introduces a variational error in the energy that potentially can be tested and systematically improved. Here, we present a computational method that produces trial wavefunctions with systematically improvable nodes for DMC calculations of periodic solids. These trial wavefunctions are efficiently generated with the configuration interaction using a perturbative selection made iteratively (CIPSI) method. A simple protocol in which both exact and approximate results for finite supercells are used to extrapolate to the thermodynamic limit is introduced.

Published

2020

3. QMCPACK : An open source ab initio Quantum Monte Carlo package for the electronic structure of atoms, molecules, and solids

Author

Kim, Jeongnim, Baczewski, Andrew, Beaudet, Todd D., Benali, Anouar, Bennett, M. Chandler, Berrill, Mark A., Blunt, Nick S., Borda, Edgar Josue Landinez, Casula, Michele, Ceperley, David M., Chiesa, Simone, Clark, Bryan K., Clay III, Raymond C., Delaney, Kris T., Dewing, Mark, Esler, Kenneth P., Hao, Hongxia, Heinonen, Olle, Kent, Paul R. C., Krogel, Jaron T., Kylanpaa, Ilkka, Li, Ying Wai, Lopez, M. Graham, Luo, Ye, Malone, Fionn D., Martin, Richard M., Mathuriya, Amrita, McMinis, Jeremy, Melton, Cody A., Mitas, Lubos, Morales, Miguel A., Neuscamman, Eric, Parker, William D., Flores, Sergio D. Pineda, Romero, Nichols A., Rubenstein, Brenda M., Shea, Jacqueline A. R., Shin, Hyeondeok, Shulenburger, Luke, Tillack, Andreas, Townsend, Joshua P., Tubman, Norm M., Van Der Goetz, Brett, Vincent, Jordan E., Yang, D. ChangMo, Yang, Yubo, Zhang, Shuai, and Zhao, Luning

Subjects

Physics - Computational Physics, Physics - Chemical Physics

Abstract

QMCPACK is an open source quantum Monte Carlo package for ab-initio electronic structure calculations. It supports calculations of metallic and insulating solids, molecules, atoms, and some model Hamiltonians. Implemented real space quantum Monte Carlo algorithms include variational, diffusion, and reptation Monte Carlo. QMCPACK uses Slater-Jastrow type trial wave functions in conjunction with a sophisticated optimizer capable of optimizing tens of thousands of parameters. The orbital space auxiliary field quantum Monte Carlo method is also implemented, enabling cross validation between different highly accurate methods. The code is specifically optimized for calculations with large numbers of electrons on the latest high performance computing architectures, including multicore central processing unit (CPU) and graphical processing unit (GPU) systems. We detail the program's capabilities, outline its structure, and give examples of its use in current research calculations. The package is available at http://www.qmcpack.org .

Published

2018

4. Magnitude of pseudopotential localization errors in fixed node diffusion quantum Monte Carlo

Author

Krogel, Jaron T. and Kent, Paul R. C.

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

Growth in computational resources has lead to the application of real space diffusion quantum Monte Carlo (DMC) to increasingly heavy elements. Although generally assumed to be small, we find that when using standard techniques the pseudopotential localization error can be large, on the order of an electron volt for an isolated cerium atom. We formally show that localization error can be reduced to zero with improvements to the Jastrow factor alone and we define a metric of Jastrow sensitivity that may be useful in the design of pseudopotentials. We employ an extrapolation scheme to extract the bare fixed node energy and estimate the localization error in both the locality approximation and the T-moves schemes for the Ce atom in charge states 3+ and 4+. The locality approximation exhibits the lowest Jastrow sensitivity and generally smaller localization errors than T-moves, although the locality approximation energy approaches the localization free limit from above/below for the 3+/4+ charge state. We find that energy minimized Jastrow factors including three-body electron-electron-ion terms are the most effective at reducing localization error for both the locality approximation and T-moves. Less complex or variance minimized Jastrows are generally less effective. Our results suggest that further improvements to Jastrow factors and trial wavefunction forms will be necessary to reduce localization errors to chemical accuracy in calculations of heavy elements., Comment: 8 pages, 2 figures

Published

2017

5. Phase Stability of TiO$_2$ Polymorphs from Diffusion Quantum Monte Carlo

Author

Luo, Ye, Benali, Anouar, Shulenburger, Luke, Krogel, Jaron T., Heinonen, Olle, and Kent, Paul R. C.

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

Titanium dioxide, TiO$_2$, has multiple applications in catalysis, energy conversion and memristive devices because of its electronic structure. Most of these applications utilize the naturally existing phases: rutile, anatase and brookite. Despite the simple form of TiO$_2$ and its wide uses, there is long-standing disagreement between theory and experiment on the energetic ordering of these phases that has never been resolved. We present the first analysis of phase stability at zero temperature using the highly accurate many-body fixed node diffusion Quantum Monte Carlo (QMC) method. We also include the effects of temperature by calculating the Helmholtz free energy including both internal energy and vibrational contributions from density functional perturbation theory based quasi harmonic phonon calculations. Our QMC calculations find that anatase is the most stable phase at zero temperature, consistent with many previous mean-field calculations. However, at elevated temperatures, rutile becomes the most stable phase. For all finite temperatures, brookite is always the least stable phase.

Published

2016