Your search keyword '"Dasgupta, Saswata"' showing total 4 results

1. Density functional theory of waterwith the machine-learned DM21 functional.

Author

Palos, Etienne, Lambros, Eleftherios, Dasgupta, Saswata, and Paesani, Francesco

Subjects

DENSITY functional theory, WATER clusters, WATER temperature, ENERGY consumption

Abstract

The delicate interplay between functional-driven and density-driven errors in density functional theory (DFT) has hindered traditional density functional approximations (DFAs) from providing an accurate description of water for over 30 years. Recently, the deep-learned DeepMind 21 (DM21) functional has been shown to overcome the limitations of traditional DFAs as it is free of delocalization error. To determine if DM21 can enable a molecular-level description of the physical properties of aqueous systems within Kohn–Sham DFT, we assess the accuracy of the DM21 functional for neutral, protonated, and deprotonated water clusters. We find that the ability of DM21 to accurately predict the energetics of aqueous clusters varies significantly with cluster size. Additionally, we introduce the many-body MB-DM21 potential derived from DM21 data within the many-body expansion of the energy and use it in simulations of liquid water as a function of temperature at ambient pressure. We find that size-dependent functional-driven errors identified in the analysis of the energetics of small clusters calculated with the DM21 functional result in the MB-DM21 potential systematically overestimating the hydrogen-bond strength and, consequently, predicting a more ice-like local structure of water at room temperature. [ABSTRACT FROM AUTHOR]

Published

2022

2. Elevating density functional theory to chemical accuracy for water simulations through a density-corrected many-body formalism.

Author

Dasgupta, Saswata, Lambros, Eleftherios, Perdew, John P., and Paesani, Francesco

Subjects

DENSITY functional theory, MOLECULAR dynamics, WATER clusters, ENERGY function, COUPLED-cluster theory

Abstract

Density functional theory (DFT) has been extensively used to model the properties of water. Albeit maintaining a good balance between accuracy and efficiency, no density functional has so far achieved the degree of accuracy necessary to correctly predict the properties of water across the entire phase diagram. Here, we present density-corrected SCAN (DC-SCAN) calculations for water which, minimizing density-driven errors, elevate the accuracy of the SCAN functional to that of "gold standard" coupled-cluster theory. Building upon the accuracy of DC-SCAN within a many-body formalism, we introduce a data-driven many-body potential energy function, MB-SCAN(DC), that quantitatively reproduces coupled cluster reference values for interaction, binding, and individual many-body energies of water clusters. Importantly, molecular dynamics simulations carried out with MB-SCAN(DC) also reproduce the properties of liquid water, which thus demonstrates that MB-SCAN(DC) is effectively the first DFT-based model that correctly describes water from the gas to the liquid phase. No existing density functional correctly describes the properties of water across the entire phase diagram. The authors report a data-driven many-body potential energy function based on density-corrected SCAN functional that quantitatively reproduces the energetics of gas-phase water clusters, and correctly predicts the properties of liquid water. [ABSTRACT FROM AUTHOR]

Published

2021

3. Standard grids for high-precision integration of modern density functionals: SG-2 and SG-3.

Author

Dasgupta, Saswata and Herbert, John M.

Subjects

*DENSITY functional theory, *APPROXIMATION theory, *QUADRATURE domains, *FUNCTIONAL analysis, *COMPUTATIONAL chemistry

Abstract

Density-functional approximations developed in the past decade necessitate the use of quadrature grids that are far more dense than those required to integrate older generations of functionals. This category of difficult-to-integrate functionals includes meta-generalized gradient approximations, which depend on orbital gradients and/or the Laplacian of the density, as well as functionals based on B97 and the popular 'Minnesota' class of functionals, each of which contain complicated and/or oscillatory expressions for the exchange inhomogeneity factor. Following a strategy introduced previously by Gill and co-workers to develop the relatively sparse 'SG-0' and 'SG-1' standard quadrature grids, we introduce two higher-quality grids that we designate SG-2 and SG-3, obtained by systematically 'pruning' medium- and high-quality atom-centered grids. The pruning procedure affords computational speedups approaching a factor of two for hybrid functionals applied to systems of [ABSTRACT FROM AUTHOR]

Published

2017

4. Ab-Initio Implementation of Ground and Excited StateResonance Raman Spectroscopy: Application to CondensedPhase and Progress Towards Biomolecules

Author

Dasgupta, Saswata

Subjects

Chemistry, Physical Chemistry, Electronic Structure Theory, Quantum Chemistry, Resonance-Raman Spectroscopy, Density Functional Theory, Enzymatic reactions, Femtosecond stimulated Raman spectroscopy

Abstract

We discuss the development and application of multiple methodologies which will either make the traditional electronic structure methods more efficient or reveal the structural insight of condensed or gas-phase systems. The main idea revolves around the development and application of \textit{ab initio} resonance-Raman (RR) spectroscopy and how to achieve the efficiency to simulate the resonance-Raman spectra for biomolecules.To tackle this, the first step was the development of new quadrature grids for high precision integration of modern density functionals, as the choice of density functional for RR simulation stems from the former's accuracy and cost-effectiveness. Our pruned integration grids, SG-2 and SG-3 work well for modern difficult-to-integrate functionals alongside finding a balance between accuracy and computational cost.To calculate the vibrational spectra for a biomolecule, getting the optimized structure is important as normal mode analysis can be erroneous at a non-stationary point. All quantum-mechanical optimization of enzyme active sites can be tricky geometric constraints that need to be introduced to prevent the structural collapse of the model system during geometry optimizations that do not contain a full protein backbone. We introduce a simple alternative in which terminal atoms of the model system are placed in soft harmonic confining potentials rather than being rigidly constrained. The new approach is more efficient for optimizing minima and transition states, as compared to the use of fixed-atom constraints, and also more robust against unwanted imaginary frequencies. To calculate the RR intensities using all-electron quantum chemistry, we used the excited state gradient method under the independent mode displaced harmonic oscillator (IMDHO) approximation. Using the RR spectroscopy we get insightful information about the structure of the hydrated electron, which caused a decade long debate. Furthermore, we have integrated the \textit{ab-initio} molecular dynamics (AIMD) simulation of excited states along with the resonance Raman calculation to substantiate the experimental femtosecond stimulated Raman spectra (FSRS) spectra. This formalism helps us to understand the time-dependent evolution of specific vibrational modes.

Published

2020