Your search keyword '"Rubenstein, Brenda"' showing total 7 results

1. A combined first principles study of the structural, magnetic, and phonon properties of monolayer CrI3.

Author

Staros, Daniel, Hu, Guoxiang, Tiihonen, Juha, Nanguneri, Ravindra, Krogel, Jaron, Bennett, M. Chandler, Heinonen, Olle, Ganesh, Panchapakesan, and Rubenstein, Brenda

Subjects

MAGNETIC anisotropy, PHONONS, MAGNETIC moments, MONOMOLECULAR films, DENSITY functional theory, LATTICE constants, MAGNETIC properties

Abstract

The first magnetic 2D material discovered, monolayer (ML) CrI3, is particularly fascinating due to its ground state ferromagnetism. However, because ML materials are difficult to probe experimentally, much remains unresolved about ML CrI3's structural, electronic, and magnetic properties. Here, we leverage Density Functional Theory (DFT) and high-accuracy Diffusion Monte Carlo (DMC) simulations to predict lattice parameters, magnetic moments, and spin–phonon and spin–lattice coupling of ML CrI3. We exploit a recently developed surrogate Hessian DMC line search technique to determine CrI3's ML geometry with DMC accuracy, yielding lattice parameters in good agreement with recently published STM measurements—an accomplishment given the ∼10% variability in previous DFT-derived estimates depending upon the functional. Strikingly, we find that previous DFT predictions of ML CrI3's magnetic spin moments are correct on average across a unit cell but miss critical local spatial fluctuations in the spin density revealed by more accurate DMC. DMC predicts that magnetic moments in ML CrI3 are 3.62 μB per chromium and −0.145 μB per iodine, both larger than previous DFT predictions. The large disparate moments together with the large spin–orbit coupling of CrI3's I-p orbital suggest a ligand superexchange-dominated magnetic anisotropy in ML CrI3, corroborating recent observations of magnons in its 2D limit. We also find that ML CrI3 exhibits a substantial spin–phonon coupling of ∼3.32 cm−1. Our work, thus, establishes many of ML CrI3's key properties, while also continuing to demonstrate the pivotal role that DMC can assume in the study of magnetic and other 2D materials. [ABSTRACT FROM AUTHOR]

Published

2022

2. Real-time dynamics of strongly correlated fermions using auxiliary field quantum Monte Carlo.

Author

Church, Matthew S. and Rubenstein, Brenda M.

Subjects

*MONTE Carlo method, *FERMIONS, *HUBBARD model, *ELECTRON configuration, *ULTRACOLD molecules, *TIME-resolved spectroscopy, *ELECTRONIC probes, *ELECTRON-electron interactions

Abstract

Spurred by recent technological advances, there is a growing demand for computational methods that can accurately predict the dynamics of correlated electrons. Such methods can provide much-needed theoretical insights into the electron dynamics probed via time-resolved spectroscopy experiments and observed in non-equilibrium ultracold atom experiments. In this article, we develop and benchmark a numerically exact Auxiliary Field Quantum Monte Carlo (AFQMC) method for modeling the dynamics of correlated electrons in real time. AFQMC has become a powerful method for predicting the ground state and finite temperature properties of strongly correlated systems mostly by employing constraints to control the sign problem. Our initial goal in this work is to determine how well AFQMC generalizes to real-time electron dynamics problems without constraints. By modeling the repulsive Hubbard model on different lattices and with differing initial electronic configurations, we show that real-time AFQMC is capable of accurately capturing long-lived electronic coherences beyond the reach of mean field techniques. While the times to which we can meaningfully model decrease with increasing correlation strength and system size as a result of the exponential growth of the dynamical phase problem, we show that our technique can model the short-time behavior of strongly correlated systems to very high accuracy. Crucially, we find that importance sampling, combined with a novel adaptive active space sampling technique, can substantially lengthen the times to which we can simulate. These results establish real-time AFQMC as a viable technique for modeling the dynamics of correlated electron systems and serve as a basis for future sampling advances that will further mitigate the dynamical phase problem. [ABSTRACT FROM AUTHOR]

Published

2021

3. Finite temperature auxiliary field quantum Monte Carlo in the canonical ensemble.

Author

Yuan Liu, Tong Shen, Yang Yu, and Rubenstein, Brenda M.

Subjects

CANONICAL ensemble, QUANTUM Monte Carlo method, MANY-body problem, HUBBARD model, CHEMICAL potential, MONTE Carlo method

Abstract

Finite temperature auxiliary field-based quantum Monte Carlo methods, including determinant quantum Monte Carlo and Auxiliary Field Quantum Monte Carlo (AFQMC), have historically assumed pivotal roles in the investigation of the finite temperature phase diagrams of a wide variety of multidimensional lattice models and materials. Despite their utility, however, these techniques are typically formulated in the grand canonical ensemble, which makes them difficult to apply to condensates such as superfluids and difficult to benchmark against alternative methods that are formulated in the canonical ensemble. Working in the grand canonical ensemble is furthermore accompanied by the increased overhead associated with having to determine the chemical potentials that produce desired fillings. Given this backdrop, in this work, we present a new recursive approach for performing AFQMC simulations in the canonical ensemble that does not require knowledge of chemical potentials. To derive this approach, we exploit the convenient fact that AFQMC solves the many-body problem by decoupling many-body propagators into integrals over one-body problems to which non-interacting theories can be applied. We benchmark the accuracy of our technique on illustrative Bose and Fermi--Hubbard models and demonstrate that it can converge more quickly to the ground state than grand canonical AFQMC simulations. We believe that our novel use of HS-transformed operators to implement algorithms originally derived for non-interacting systems will motivate the development of a variety of other methods and anticipate that our technique will enable direct performance comparisons against other many-body approaches formulated in the canonical ensemble. [ABSTRACT FROM AUTHOR]

Published

2020

4. QMCPACK: Advances in the development, efficiency, and application of auxiliary field and real-space variational and diffusion quantum Monte Carlo.

Author

Kent, P. R. C., Annaberdiyev, Abdulgani, Benali, Anouar, Bennett, M. Chandler, Landinez Borda, Edgar Josué, Doak, Peter, Hao, Hongxia, Jordan, Kenneth D., Krogel, Jaron T., Kylänpää, Ilkka, Lee, Joonho, Luo, Ye, Malone, Fionn D., Melton, Cody A., Mitas, Lubos, Morales, Miguel A., Neuscamman, Eric, Reboredo, Fernando A., Rubenstein, Brenda, and Saritas, Kayahan

Subjects

PSEUDOPOTENTIAL method, DIFFUSION, ELECTRONIC structure, SURFACE states, LATTICE dynamics

Abstract

We review recent advances in the capabilities of the open source ab initio Quantum Monte Carlo (QMC) package QMCPACK and the workflow tool Nexus used for greater efficiency and reproducibility. The auxiliary field QMC (AFQMC) implementation has been greatly expanded to include k-point symmetries, tensor-hypercontraction, and accelerated graphical processing unit (GPU) support. These scaling and memory reductions greatly increase the number of orbitals that can practically be included in AFQMC calculations, increasing the accuracy. Advances in real space methods include techniques for accurate computation of bandgaps and for systematically improving the nodal surface of ground state wavefunctions. Results of these calculations can be used to validate application of more approximate electronic structure methods, including GW and density functional based techniques. To provide an improved foundation for these calculations, we utilize a new set of correlation-consistent effective core potentials (pseudopotentials) that are more accurate than previous sets; these can also be applied in quantum-chemical and other many-body applications, not only QMC. These advances increase the efficiency, accuracy, and range of properties that can be studied in both molecules and materials with QMC and QMCPACK. [ABSTRACT FROM AUTHOR]

Published

2020

5. A combined first principles study of the structural, magnetic, and phonon properties of monolayer CrI3.

Author

Staros, Daniel, Hu, Guoxiang, Tiihonen, Juha, Nanguneri, Ravindra, Krogel, Jaron, Bennett, M. Chandler, Heinonen, Olle, Ganesh, Panchapakesan, and Rubenstein, Brenda

Subjects

*MAGNETIC anisotropy, *PHONONS, *MAGNETIC moments, *MONOMOLECULAR films, *DENSITY functional theory, *LATTICE constants, *MAGNETIC properties

Abstract

The first magnetic 2D material discovered, monolayer (ML) CrI3, is particularly fascinating due to its ground state ferromagnetism. However, because ML materials are difficult to probe experimentally, much remains unresolved about ML CrI3's structural, electronic, and magnetic properties. Here, we leverage Density Functional Theory (DFT) and high-accuracy Diffusion Monte Carlo (DMC) simulations to predict lattice parameters, magnetic moments, and spin–phonon and spin–lattice coupling of ML CrI3. We exploit a recently developed surrogate Hessian DMC line search technique to determine CrI3's ML geometry with DMC accuracy, yielding lattice parameters in good agreement with recently published STM measurements—an accomplishment given the ∼10% variability in previous DFT-derived estimates depending upon the functional. Strikingly, we find that previous DFT predictions of ML CrI3's magnetic spin moments are correct on average across a unit cell but miss critical local spatial fluctuations in the spin density revealed by more accurate DMC. DMC predicts that magnetic moments in ML CrI3 are 3.62 μB per chromium and −0.145 μB per iodine, both larger than previous DFT predictions. The large disparate moments together with the large spin–orbit coupling of CrI3's I-p orbital suggest a ligand superexchange-dominated magnetic anisotropy in ML CrI3, corroborating recent observations of magnons in its 2D limit. We also find that ML CrI3 exhibits a substantial spin–phonon coupling of ∼3.32 cm−1. Our work, thus, establishes many of ML CrI3's key properties, while also continuing to demonstrate the pivotal role that DMC can assume in the study of magnetic and other 2D materials. [ABSTRACT FROM AUTHOR]

Published

2022

6. A combined first principles study of the structural, magnetic, and phonon properties of monolayer CrI 3 .

Author

Staros D, Hu G, Tiihonen J, Nanguneri R, Krogel J, Bennett MC, Heinonen O, Ganesh P, and Rubenstein B

Abstract

The first magnetic 2D material discovered, monolayer (ML) CrI 3 , is particularly fascinating due to its ground state ferromagnetism. However, because ML materials are difficult to probe experimentally, much remains unresolved about ML CrI 3 's structural, electronic, and magnetic properties. Here, we leverage Density Functional Theory (DFT) and high-accuracy Diffusion Monte Carlo (DMC) simulations to predict lattice parameters, magnetic moments, and spin-phonon and spin-lattice coupling of ML CrI 3 . We exploit a recently developed surrogate Hessian DMC line search technique to determine CrI 3 's ML geometry with DMC accuracy, yielding lattice parameters in good agreement with recently published STM measurements-an accomplishment given the ∼10% variability in previous DFT-derived estimates depending upon the functional. Strikingly, we find that previous DFT predictions of ML CrI 3 's magnetic spin moments are correct on average across a unit cell but miss critical local spatial fluctuations in the spin density revealed by more accurate DMC. DMC predicts that magnetic moments in ML CrI 3 are 3.62 μ B per chromium and -0.145 μ B per iodine, both larger than previous DFT predictions. The large disparate moments together with the large spin-orbit coupling of CrI 3 's I-p orbital suggest a ligand superexchange-dominated magnetic anisotropy in ML CrI 3 , corroborating recent observations of magnons in its 2D limit. We also find that ML CrI 3 exhibits a substantial spin-phonon coupling of ∼3.32 cm -1 . Our work, thus, establishes many of ML CrI 3 's key properties, while also continuing to demonstrate the pivotal role that DMC can assume in the study of magnetic and other 2D materials.

Published

2022

7. Finite temperature auxiliary field quantum Monte Carlo in the canonical ensemble.

Author

Shen T, Liu Y, Yu Y, and Rubenstein BM

Abstract

Finite temperature auxiliary field-based quantum Monte Carlo methods, including determinant quantum Monte Carlo and Auxiliary Field Quantum Monte Carlo (AFQMC), have historically assumed pivotal roles in the investigation of the finite temperature phase diagrams of a wide variety of multidimensional lattice models and materials. Despite their utility, however, these techniques are typically formulated in the grand canonical ensemble, which makes them difficult to apply to condensates such as superfluids and difficult to benchmark against alternative methods that are formulated in the canonical ensemble. Working in the grand canonical ensemble is furthermore accompanied by the increased overhead associated with having to determine the chemical potentials that produce desired fillings. Given this backdrop, in this work, we present a new recursive approach for performing AFQMC simulations in the canonical ensemble that does not require knowledge of chemical potentials. To derive this approach, we exploit the convenient fact that AFQMC solves the many-body problem by decoupling many-body propagators into integrals over one-body problems to which non-interacting theories can be applied. We benchmark the accuracy of our technique on illustrative Bose and Fermi-Hubbard models and demonstrate that it can converge more quickly to the ground state than grand canonical AFQMC simulations. We believe that our novel use of HS-transformed operators to implement algorithms originally derived for non-interacting systems will motivate the development of a variety of other methods and anticipate that our technique will enable direct performance comparisons against other many-body approaches formulated in the canonical ensemble.

Published

2020