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33 results on '"Gavartin, Jacob"'

1. Robust and effective ab initio molecular dynamics simulations on the GPU cloud infrastructure using the Schr\'odinger Materials Science Suite

Author

Fonari, Alexandr, Agarwal, Garvit, Tiwari, Subodh C., Brock, Casey N., Gavartin, Jacob, and Halls, Mathew D.

Subjects
Condensed Matter - Materials Science
Abstract

Ab initio Born-Oppenheimer molecular dynamics (AIMD) is a valuable method for simulating physico-chemical processes of complex systems, including reactive systems, and for training machine learning models and force fields. Speed and stability issues on traditional hardware preclude routine AIMD simulations for larger systems and longer timescales. We postulate that any practically useful AIMD simulation must generate a trajectory of a minimum 1000 MD steps a day on a moderate cloud resource. In this work, we implement a computing workflow that enables routine calculations at this throughput and demonstrate results for several non-trivial atomistic dynamical systems. In particular, we have employed the GPU implementation of the Quantum ESPRESSO code which we will show increases AIMD productivity compared to the CPU version. In order to take advantage of transient servers (which are more cost and energy effective compared to the stable servers), we have implemented automatic restart/continuation of the AIMD runs within the Schr\"odinger Materials Science Suite. Finally, to reduce simulation size and thus reduce compute time when modeling surfaces, we have implemented a wall potential constraint. Our benchmarks using several reactive systems (lithium anode surface/solvent interface, hydrogen diffusion in an iron grain boundary) show a significant speed up when running on a GPU-enabled transient server using our updated implementation.

Published
2024
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4. Modelling charge self-trapping in wide-gap dielectrics: Localization problem in local density functionals

Author

Gavartin, Jacob L., Sushko, Peter V., and Shluger, Alexander L.

Subjects
Condensed Matter
Abstract

We discuss the adiabatic self-trapping of small polarons within the density functional theory (DFT). In particular, we carried out plane-wave pseudo-potential calculations of the triplet exciton in NaCl and found no energy minimum corresponding to the self-trapped exciton (STE) contrary to the experimental evidence and previous calculations. To explore the origin of this problem we modelled the self-trapped hole in NaCl using hybrid density functionals and an embedded cluster method. Calculations show that the stability of the self-trapped state of the hole drastically depends on the amount of the exact exchange in the density functional: at less than 30% of the Hartree-Fock exchange, only delocalized hole is stable, at 50% - both delocalized and self-trapped states are stable, while further increase of exact exchange results in only the self-trapped state being stable. We argue that the main contributions to the self-trapping energy such as the kinetic energy of the localizing charge, the chemical bond formation of the di-halogen quasi molecule, and the lattice polarization, are represented incorrectly within the Kohn-Sham (KS) based approaches., Comment: 6 figures, 1 table

Published
2002
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9. Electronic properties of structural defects at the MgO (001) surface

Author

Sushko, Peter V., Gavartin, Jacob L., and Shluger, Alexander L.

Subjects
Chemistry, Physical and theoretical -- Research, Dissociation -- Physiological aspects, Adsorption -- Physiological aspects, Surface chemistry -- Research, Ionization -- Physiological aspects, Oxygen -- Physiological aspects, Magnesium -- Physiological aspects, Chemicals, plastics and rubber industries
Published
2002

16. Virtual screening for OLED materials

Author

Halls, Mathew D., additional, Giesen, David J., additional, Hughes, Thomas F., additional, Goldberg, Alexander, additional, Cao, Yixiang, additional, Kwak, H. Shaun, additional, and Gavartin, Jacob, additional

Published
2014
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18. Exploring Fuel Cell Cathode Materials: A High Throughput Calculation Approach

Author

Gavartin, Jacob, primary, Sarwar, Misbah, additional, Papageorgopoulos, Dimitrios, additional, Gunn, David, additional, Garcia, Sonia, additional, Perlov, Alexander, additional, Krzystala, Arek, additional, Ormsby, Dan L., additional, Thompsett, David, additional, Goldbeck-Wood, Gerhard, additional, Andersen, Amity, additional, and French, Sam, additional

Published
2009
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29. Discovery of New Anode SEI Forming Additives Using an in silico Evolutionary Approach

Author

Murdock, Stuart E., Hughes, Thomas F., Kwak, Shaun H., Goldberg, Alexander, Giesen, David J, Cao, Yixiang, Sanders, Jeffrey, Gavartin, Jacob, Dathar, Phani, and Halls, Mathew D.

Abstract

To improve the performance of lithium ion batteries, functional additives are included in electrolyte formulations. To reduce damage to the electrolyte when a cell is charged, sacrificial anode SEI forming additives are used, requiring high reduction potential and high reactivity. Previously, high throughput quantum chemical screening of structure libraries has been demonstrated for electrolyte component discovery, but this can be a time consuming and highly curated procedure. An alternative approach involves the automated evolution of a set of input structures toward target property characteristics. This requires less user management and enables knowledge creation rather than knowledge implementation. In this work, a quantum chemistry based genetic optimization framework is applied to battery electrolyte components for the first time, seeking to simultaneously maximize reduction potential and minimize oxidation potential for evolved candidate anode SEI additives.

Published
2015

31. Atomistic modelling of radiation effects: Towards dynamics of exciton relaxation

Author

Shluger, Alexander L, Gavartin, Jacob L, Szymanski, Marek A, and Marshall Stoneham, A

Abstract

This brief review is focused on recent results of atomistic modelling and simulation of exciton related processes in ionic materials. We present an analysis of thermal fluctuations of the electrostatic potential in cubic ionic crystals and their relation to formation of a tail in the electron density of states and localisation of electronic states. Then the possible ‘fast’ mechanism of formation of F–H pairs in KBr as a result of decomposition of relaxing excitons is discussed. We briefly describe some ideas related to the possibility of coherent control of exciton decomposition into Frenkel defects in alkali halides. Next we turn to the results of modelling of exciton excitation and localisation at the low-coordinated surface sites of MgO. And finally, we present the results of quantum-mechanical simulation of peroxy linkages and their reaction which creates oxygen molecules in silica.

Published
2000
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33. Discovery of New Anode SEI Forming Additives Using an in silicoEvolutionary Approach

Author

Murdock, Stuart E., Hughes, Thomas F., Kwak, Shaun H., Goldberg, Alexander, Giesen, David J, Cao, Yixiang, Sanders, Jeffrey, Gavartin, Jacob, Dathar, G. K. Phani, and Halls, Mathew D.

Abstract

To improve the performance of lithium ion batteries, functional additives are included in electrolyte formulations. To reduce damage to the electrolyte when a cell is charged, sacrificial anode SEI forming additives are used, requiring high reduction potential and high reactivity. Previously, high throughput quantum chemical screening of structure libraries has been demonstrated for electrolyte component discovery, but this can be a time consuming and highly curated procedure. An alternative approach involves the automated evolution of a set of input structures toward target property characteristics. This requires less user management and enables knowledge creation rather than knowledge implementation. In this work, a quantum chemistry based genetic optimization framework is applied to battery electrolyte components for the first time, seeking to simultaneously maximize reduction potential and minimize oxidation potential for evolved candidate anode SEI additives.

Published
2015
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