Your search keyword '"Clay III, Raymond C."' showing total 15 results

1. Towards Quantum Monte Carlo Forces on Heavier Ions: Scaling Properties

Author

Tiihonen, Juha, Clay III, Raymond C., and Krogel, Jaron T.

Subjects

Physics - Computational Physics

Abstract

Quantum Monte Carlo (QMC) forces have been studied extensively in recent decades because of their importance with spectroscopic observables and geometry optimization. Here we benchmark the accuracy and statistical cost of QMC forces. The zero-variance zero-bias (ZVZB) force estimator is used in standard variational and diffusion Monte Carlo simulations with mean-field based trial wavefunctions and atomic pseudopotentials. Statistical force uncertainties are obtained with a recently developed regression technique for heavy tailed QMC data [P. Lopez Rios and G. J. Conduit, Phys. Rev. E 99, 063312 (2019)]. By considering selected atoms and dimers with elements ranging from H to Zn ($1\leq Z_{\mathrm{eff}} \leq 20$), we assess the accuracy and the computational cost of ZVZB forces as the effective pseudopotential valence charge, $Z_{\mathrm{eff}}$, increases. We find that the cost of QMC energies and forces approximately follow simple power laws in $Z_{\mathrm{eff}}$. The force uncertainty grows more rapidly, leading to a best case cost scaling relationship of approximately $Z_{\mathrm{eff}}^{6.5(3)}$ for DMC. We find the affordable system size decreases as $Z_{\mathrm{eff}}^{-2}$, insensitive to model assumptions or the use of "space warp" variance reduction. Our results predict the practical cost of obtaining forces for a range of materials, such as transition metal oxides where QMC forces have yet to be applied, and underscore the importance of further developing force variance reduction techniques, particularly for atoms with high $\zeff$., Comment: 12 pages, 7 figures

Published

2021

2. Efficacy of the Radial Pair Potential Approximation for Molecular Dynamics Simulations of Dense Plasmas

Author

Stanek, Lucas J., Clay III, Raymond C., Dharma-wardana, M. W. C., Wood, Mitchell A., Beckwith, Kristian R. C., and Murillo, Michael S.

Subjects

Physics - Plasma Physics

Abstract

Macroscopic simulations of dense plasmas rely on detailed microscopic information that can be computationally expensive and is difficult to verify experimentally. In this work, we delineate the accuracy boundary between microscale simulation methods by comparing Kohn-Sham density functional theory molecular dynamics (KS-MD) and radial pair potential molecular dynamics (RPP- MD) for a range of elements, temperature, and density. By extracting the optimal RPP from KS-MD data using force-matching, we constrain its functional form and dismiss classes of potentials that assume a constant power law for small interparticle distances. Our results show excellent agreement between RPP-MD and KS-MD for multiple metrics of accuracy at temperatures of only a few electron volts. The use of RPPs offers orders of magnitude decrease in computational cost and indicates that three-body potentials are not required beyond temperatures of a few eV. Due to its efficiency, the validated RPP-MD provides an avenue for reducing errors due to finite-size effects that can be on the order of $\sim20\%$.

Published

2020

3. Towards a systematically improvable many-body description of antiferromagnetic iron oxide

Author

Townsend, Joshua P, Clay III, Raymond C, Mattsson, Thomas R, Neuscamman, Eric, Zhao, Luning, Esler, Ken, Cohen, Ronald E, and Shulenburger, Luke

Subjects

Condensed Matter - Materials Science

Abstract

We report variational and fixed-node diffusion quantum Monte Carlo (QMC) calculations of anti-ferromagnetic iron oxide (FeO) in the ground state B1 crystal structure. The goal of this study was a systematic investigation of the sensitivity of several ground state properties to a variety of QMC wave function generation techniques including advanced wave functions such as multi-determinant expansions and backflow transformations. We found that the predicted lattice distortion was largely controlled by the choice of single particle orbitals used to construct the wave function, rather than by subsequent wave function optimization techniques within QMC. However, the absolute magnetic moment was remarkably insensitive to the method of wave function construction. QMC estimates of total spin density indicate that in addition to strong electronic correlation of the Fe $3d$ states, charge transfer may be an important but challenging piece of physics to accurately capture within existing QMC methods. Finally, we highlight the need for advanced and systematically improvable many-body wave functions suitable for accurately describing challenging real systems., Comment: Further calculations are in progress. This version does not accurately represent the results of our investigation

Published

2018

4. 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

5. Embracing a new era of highly efficient and productive quantum Monte Carlo simulations

Author

Mathuriya, Amrita, Luo, Ye, Clay III, Raymond C., Benali, Anouar, Shulenburger, Luke, and Kim, Jeongnim

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing

Abstract

QMCPACK has enabled cutting-edge materials research on supercomputers for over a decade. It scales nearly ideally but has low single-node efficiency due to the physics-based abstractions using array-of-structures objects, causing inefficient vectorization. We present a systematic approach to transform QMCPACK to better exploit the new hardware features of modern CPUs in portable and maintainable ways. We develop miniapps for fast prototyping and optimizations. We implement new containers in structure-of-arrays data layout to facilitate vectorizations by the compilers. Further speedup and smaller memory-footprints are obtained by computing data on the fly with the vectorized routines and expanding single-precision use. All these are seamlessly incorporated in production QMCPACK. We demonstrate upto 4.5x speedups on recent Intel processors and IBM Blue Gene/Q for representative workloads. Energy consumption is reduced significantly commensurate to the speedup factor. Memory-footprints are reduced by up-to 3.8x, opening the possibility to solve much larger problems of future., Comment: 12 pages, 10 figures, 2 tables, to be published at SC17

Published

2017

6. Theory of Finite Size Effects for Electronic Quantum Monte Carlo Calculations of Liquids and Solids

Author

Holzmann, Markus, Clay III, Raymond C., Morales, Miguel A., Tubman, Norm M., Ceperley, David M., and Pierleoni, Carlo

Subjects

Physics - Computational Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons

Abstract

Concentrating on zero temperature Quantum Monte Carlo calculations of electronic systems, we give a general description of the theory of finite size extrapolations of energies to the thermodynamic limit based on one and two-body correlation functions. We introduce new effective procedures, such as using the potential and wavefunction split-up into long and short range functions to simplify the method and we discuss how to treat backflow wavefunctions. Then we explicitly test the accuracy of our method to correct finite size errors on example hydrogen and helium many-body systems and show that the finite size bias can be drastically reduced for even small systems., Comment: 22 pages, 5 figures

Published

2016

7. Benchmarking Hydrogen-Helium Mixtures with QMC: Energetics, Pressures, and Forces

Author

Clay III, Raymond C., Holzmann, Markus, Ceperley, David M., and Morales, Miguel A.

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

An accurate understanding of the phase diagram of dense hydrogen and helium mixtures is a crucial component in the construction of accurate models of Jupiter, Saturn, and Jovian extrasolar planets. Though DFT based first principles methods have the potential to provide the accuracy and computational efficiency required for this task, recent benchmarking in hydrogen has shown that achieving this accuracy requires a judicious choice of functional, and a quantification of the errors introduced. In this work, we present a quantum Monte Carlo based benchmarking study of a wide range of density functionals for use in hydrogen-helium mixtures at thermodynamic conditions relevant for Jovian planets. Not only do we continue our program of benchmarking energetics and pressures, but we deploy QMC based force estimators and use them to gain insights into how well the local liquid structure is captured by different density functionals. We find that TPSS, BLYP and vdW-DF are the most accurate functionals by most metrics, and that the enthalpy, energy, and pressure errors are very well behaved as a function of helium concentration. Beyond this, we highlight and analyze the major error trends and relative differences exhibited by the major classes of functionals, and estimate the magnitudes of these effects when possible., Comment: Supplemental info included

Published

2015

8. Review of the second charged-particle transport coefficient code comparison workshop.

Author

Stanek, Lucas J., Kononov, Alina, Hansen, Stephanie B., Haines, Brian M., Hu, S. X., Knapp, Patrick F., Murillo, Michael S., Stanton, Liam G., Whitley, Heather D., Baalrud, Scott D., Babati, Lucas J., Baczewski, Andrew D., Bethkenhagen, Mandy, Blanchet, Augustin, Clay III, Raymond C., Cochrane, Kyle R., Collins, Lee A., Dumi, Amanda, Faussurier, Gerald, and French, Martin

Subjects

TIME-dependent density functional theory, THERMAL electrons, THERMAL conductivity, ALPHA rays, IONIC structure, ELECTRIC conductivity, ELECTRONIC structure

Abstract

We report the results of the second charged-particle transport coefficient code comparison workshop, which was held in Livermore, California on 24–27 July 2023. This workshop gathered theoretical, computational, and experimental scientists to assess the state of computational and experimental techniques for understanding charged-particle transport coefficients relevant to high-energy-density plasma science. Data for electronic and ionic transport coefficients, namely, the direct current electrical conductivity, electron thermal conductivity, ion shear viscosity, and ion thermal conductivity were computed and compared for multiple plasma conditions. Additional comparisons were carried out for electron–ion properties such as the electron–ion equilibration time and alpha particle stopping power. Overall, 39 participants submitted calculated results from 18 independent approaches, spanning methods from parameterized semi-empirical models to time-dependent density functional theory. In the cases studied here, we find significant differences—several orders of magnitude—between approaches, particularly at lower temperatures, and smaller differences—roughly a factor of five—among first-principles models. We investigate the origins of these differences through comparisons of underlying predictions of ionic and electronic structure. The results of this workshop help to identify plasma conditions where computationally inexpensive approaches are accurate, where computationally expensive models are required, and where experimental measurements will have high impact. [ABSTRACT FROM AUTHOR]

Published

2024

9. Transport coefficients of warm dense matter from Kohn-Sham density functional theory.

Author

Melton, Cody A., Clay III, Raymond C., Cochrane, Kyle R., Dumi, Amanda, Gardiner, Thomas A., Lentz, Meghan K., and Townsend, Joshua P.

Subjects

*DENSITY functional theory, *KRAMERS-Kronig relations, *MOLECULAR dynamics, *THERMAL conductivity, *OPTICAL properties, *ELECTRIC stimulation

Abstract

We present a comprehensive study of transport coefficients including DC electrical conductivity and related optical properties, electrical contribution to the thermal conductivity, and the shear viscosity via ab initio molecular dynamics and density functional theory calculations on the "priority 1" cases from the "Second Charged-Particle Transport Coefficient Workshop" [Stanek et al., Phys. Plasmas (to be published 2024)]. The purpose of this work is to carefully document the entire workflow used to generate our reported transport coefficients, up to and including our definitions of finite size and statistical convergence, extrapolation techniques, and choice of thermodynamic ensembles. In pursuit of accurate optical properties, we also present a novel, simple, and highly accurate algorithm for evaluating the Kramers–Kronig relations. These heuristics are often not discussed in the literature, and it is hoped that this work will facilitate the reproducibility of our data. [ABSTRACT FROM AUTHOR]

Published

2024

10. Experimental Validation of Dense Plasma Transport Models using the Z-Machine.

Author

Knapp, Patrick, primary, Beckwith, Kristian, additional, Cochrane, Kyle, additional, Clay, III, Raymond C., additional, and Mattsson, Thomas, additional

Published

2019

11. Influence of single particle orbital sets and configuration selection on multideterminant wavefunctions in quantum Monte Carlo.

Author

Clay III, Raymond C. and Morales, Miguel A.

Subjects

*WAVE functions, *QUANTUM chemistry, *QUANTUM Monte Carlo method, *DIMERS, *STATISTICAL correlation

Abstract

Multideterminant wavefunctions, while having a long history in quantum chemistry, are increasingly being used in highly accurate quantum Monte Carlo calculations. Since the accuracy of QMC is ultimately limited by the quality of the trial wavefunction, multi-Slater determinants wavefunctions offer an attractive alternative to Slater-Jastrow and more sophisticated wavefunction ansatz for several reasons. They can be efficiently calculated, straightforwardly optimized, and systematically improved by increasing the number of included determinants. In spite of their potential, however, the convergence properties of multi-Slater determinant wavefunctions with respect to orbital set choice and excited determinant selection are poorly understood, which hinders the application of these wavefunctions to large systems and solids. In this paper, by performing QMC calculations on the equilibrium and stretched carbon dimer, we find that convergence of the recovered correlation energy with respect to number of determinants can depend quite strongly on basis set and determinant selection methods, especially where there is strong correlation. We demonstrate that properly chosen orbital sets and determinant selection techniques from quantum chemistry methods can dramatically reduce the required number of determinants (and thus the computational cost) to reach a given accuracy, which we argue shows clear need for an automatic QMC-only method for selecting determinants and generating optimal orbital sets. [ABSTRACT FROM AUTHOR]

Published

2015

12. Efficacy of the radial pair potential approximation for molecular dynamics simulations of dense plasmas.

Author

Stanek, Lucas J., Clay III, Raymond C., Dharma-wardana, M. W. C., Wood, Mitchell A., Beckwith, Kristian R. C., and Murillo, Michael S.

Subjects

*DENSE plasmas, *DENSITY functional theory, *MOLECULAR theory, *MOLECULAR dynamics, *MAGNITUDE (Mathematics)

Abstract

Macroscopic simulations of dense plasmas rely on detailed microscopic information that can be computationally expensive and is difficult to verify experimentally. In this work, we delineate the accuracy boundary between microscale simulation methods by comparing Kohn–Sham density functional theory molecular dynamics (KS-MD) and radial pair potential molecular dynamics (RPP-MD) for a range of elements, temperature, and density. By extracting the optimal RPP from KS-MD data using force matching, we constrain its functional form and dismiss classes of potentials that assume a constant power law for small interparticle distances. Our results show excellent agreement between RPP-MD and KS-MD for multiple metrics of accuracy at temperatures of only a few electron volts. The use of RPPs offers orders of magnitude decrease in computational cost and indicates that three-body potentials are not required beyond temperatures of a few eV. Due to its efficiency, the validated RPP-MD provides an avenue for reducing errors due to finite-size effects that can be on the order of ∼ 20 %. [ABSTRACT FROM AUTHOR]

Published

2021

13. Benchmarking density functionals for hydrogen-helium mixtures with quantum Monte Carlo: Energetics, pressures, and forces.

Author

Clay III, Raymond C., Holzmann, Markus, Ceperley, David M., and Morales, Miguel A.

Subjects

*DENSITY functional theory, *MONTE Carlo method, *EXTRASOLAR planets, *ENTHALPY, *QUANTUM theory

Abstract

An accurate understanding of the phase diagram of dense hydrogen and heliummixtures is a crucial component in the construction of accurate models of Jupiter, Saturn, and Jovian extrasolar planets. Though density-functionaltheory-based first-principles methods have the potential to provide the accuracy and computational efficiency required for this task, recent benchmarking in hydrogen has shown that achieving this accuracy requires a judicious choice of functional, and a quantification of the errors introduced. In this work, we present a quantum Monte Carlo (QMC)-based benchmarking study of a wide range of density functionals for use in hydrogen-helium mixtures at thermodynamic conditions relevant for Jovian planets. Not only do we continue our program of benchmarking energetics and pressures, but we deploy QMC-based force estimators and use them to gain insight into how well the local liquid structure is captured by different density functionals.We find that TPSS, BLYP, and vdW-DF are the most accurate functionals by most metrics, and that the enthalpy, energy, and pressure errors are very well behaved as a function of helium concentration. Beyond this, we highlight and analyze the major error trends and relative differences exhibited by the major classes of functionals, and we estimate the magnitudes of these effects when possible. [ABSTRACT FROM AUTHOR]

Published

2016

14. Molecular to Atomic Phase Transition in Hydrogen under High Pressure.

Author

McMinis, Jeremy, Clay III, Raymond C., Donghwa Lee, and Morales, Miguel A.

Subjects

*HYDROGEN analysis, *HIGH pressure physics, *ATOMIC transitions, *PHASE transitions, *DENSITY functional theory, *MONTE Carlo method

Abstract

The metallization of high-pressure hydrogen, together with the associated molecular to atomic transition, is one of the most important problems in the field of high-pressure physics. It is also currently a matter of intense debate due to the existence of conflicting experimental reports on the observation of metallic hydrogen on a diamond-anvil cell. Theoretical calculations have typically relied on a mean-field description of electronic correlation through density functional theory, a theory with well-known limitations in the description of metal-insulator transitions. In fact, the predictions of the pressure-driven dissociation of molecules in high-pressure hydrogen by density functional theory is strongly affected by the chosen exchange-correlation functional. In this Letter, we use quantum Monte Carlo calculations to study the molecular to atomic transition in hydrogen. We obtain a transition pressure of 447(3) GPa, in excellent agreement with the best experimental estimate of the transition 450 GPa based on an extrapolation to zero band gap from experimental measurements. Additionally, we find that C2/c is stable almost up to the molecular to atomic transition, in contrast to previous density functional theory (DFT) and DFT + quantum Monte Carlo studies which predict large stability regimes for intermediary molecular phases. [ABSTRACT FROM AUTHOR]

Published

2015

15. Benchmarking exchange-correlation functionals for hydrogen at high pressures using quantum Monte Carlo.

Author

Clay, III, Raymond C., Mcminis, Jeremy, McMahon, Jeffrey M., Pierleoni, Carlo, Ceperley, David M., and Morales, Miguel A.

Subjects

*AB initio quantum chemistry methods, *QUANTUM theory, *MONTE Carlo method, *LIQUID-liquid transformations, *MOLECULAR dynamics

Abstract

The ab initio phase diagram of dense hydrogen is very sensitive to errors in the treatment of electronic correlation. Recently, it has been shown that the choice of the density functional has a large effect on the predicted location of both the liquid-liquid phase transition and the solid insulator-to-metal transition in dense hydrogen. To identify the most accurate functional for dense hydrogen applications, we systematically benchmark some of the most commonly used functionals using quantum Monte Carlo. By considering several measures of functional accuracy, we conclude that the van der Waals and hybrid functionals significantly outperform local density approximation and Perdew-Burke-Emzerhof. We support these conclusions by analyzing the impact of functional choice on structural optimization in the molecular solid, and on the location of the liquid-liquid phase transition. [ABSTRACT FROM AUTHOR]

Published

2014