Exploiting graphical processing units to enable quantum chemistry calculation of large solvated molecules with conductor-like polarizable continuum models

Exploiting graphical processing units to enable quantum chemistry calculation of large solvated molecules with conductor-like polarizable continuum models

The conductor‐like polarizable continuum model (C‐PCM) with switching/Gaussian smooth discretization is a widely used implicit solvation model in quantum chemistry. We have previously implemented C‐PCM solvation for Hartree‐Fock (HF) and density functional theory (DFT) on graphical processing units...

Full description

Bibliographic Details
Main Authors:	Liu, Fang, Sanchez, David M., Kulik, Heather Janine, Martínez, Todd J.
Other Authors:	Massachusetts Institute of Technology. Department of Chemical Engineering
Format:	Article
Published:	Wiley 2020
Online Access:	https://hdl.handle.net/1721.1/123830

Similar Items

Quantum Chemistry for Solvated Molecules on Graphical Processing Units Using Polarizable Continuum Models
by: Liu, Fang, et al.
Published: (2017)

Continuum modeling of polarizable systems
by: Rinaldi, Carlos (Carlos M. Rinaldi-Ramos), 1975-
Published: (2005)

How Large Should the QM Region Be in QM/MM Calculations? The Case of Catechol O-Methyltransferase
by: Zhang, Jianyu, et al.
Published: (2017)

DesDesigning in the Face of Uncertainty: Exploiting Electronic Structure and Machine Learning Models for Discovery in Inorganic Chemistry
by: Janet, Jon Paul, et al.
Published: (2021)

Application of density functional theory to calculation of in-crystal anionic polarizability
by: Domene, C, et al.
Published: (1999)

STUDI KOMPUTASI KONFORMASI DAN PENGARUH PELARUT TERHADAP ENERGI INTERAKSI PADA KOMPLEKS YTTRIUM-DOTA- DENGAN METODE C-PCM (Conductor-like Polarizable Continuum Model)
by: ROZAQ, ABDUL
Published: (2012)

Stable Surfaces That Bind Too Tightly: Can Range-Separated Hybrids or DFT+U Improve Paradoxical Descriptions of Surface Chemistry?
by: Zhao, Qing, et al.
Published: (2019)

Critical solvation structures arrested active molecules for reversible Zn electrochemistry
by: Zheng, Junjie, et al.
Published: (2024)

Learning from Failure: Predicting Electronic Structure Calculation Outcomes with Machine Learning Models
by: Duan, Chenru, et al.
Published: (2020)

Exploiting extraordinary topological optical forces at bound states in the continuum
by: Qin, Haoye, et al.
Published: (2023)

Large-scale QM/MM free energy simulations of enzyme catalysis reveal the influence of charge transfer
by: Kulik, Heather Janine
Published: (2018)

Strategies and Software for Machine Learning Accelerated Discovery in Transition Metal Chemistry
by: Nandy, Aditya, et al.
Published: (2019)

Adapting DFT+U for the Chemically Motivated Correction of Minimal Basis Set Incompleteness
by: Mar, Brendan D., et al.
Published: (2017)

Software based graphic signal calculator
by: Teo, Kai Yi
Published: (2021)

The force density in polarizable and magnetizable fluids
Published: (2004)

THE POLARIZABILITIES OF SPECIES PRESENT IN IONIC-SOLUTIONS
by: Pyper, N, et al.
Published: (1992)

The calculation of energy for atoms, molecules and crystals
by: Hassan, Zainul Abidin
Published: (1999)

Hyperelastic continuum modeling of cubic crystals based on first-principles calculations
by: Salvetti, Matteo Francesco
Published: (2011)

Trees and beyond : exploiting and improving tree-structured graphical models
by: Choi, Myung Jin, Ph. D. Massachusetts Institute of Technology
Published: (2011)

Calculation of dipole-shielding polarizabilities (sigma(alphabetagamma)I): the influence of uniform electric field effects on the shielding of backbone nuclei in proteins.
by: Boyd, J, et al.
Published: (2003)

Systematic Quantum Mechanical Region Determination in QM/MM Simulation
by: Karelina, Maria, et al.
Published: (2018)

Where Does the Density Localize in the Solid State? Divergent Behavior for Hybrids and DFT+U
by: Zhao, Qing, et al.
Published: (2018)

Non-linear electrophoresis of ideally polarizable particles
by: Chan, Wai Hong Ronald
Published: (2015)

QUANTUM-THEORY OF POLARIZABLE QUADRUPOLAR FLUIDS .1.
by: Logan, D
Published: (1984)

On the sign of regular algebraic polarizable automorphic representations
by: Patrikis, Stefan T
Published: (2016)

The effects of using graphic calculators in teaching and learning of mathematics
by: Mohd Tajudin, Nor’ain, et al.
Published: (2007)

The solvation structure of alprazolam
by: Sridhar, A, et al.
Published: (2016)

SOLVATION - GENERAL DISCUSSION
by: Chandler, D, et al.
Published: (1988)

Deshielding anions enable solvation chemistry control of LiPF6-based electrolyte toward low-temperature lithium-ion batteries
by: Yuan, Song, et al.
Published: (2024)

Instructional efficiency of the integration of graphic calculators in teaching and learning mathematics.
by: Mohd Tajuddin, Nor’ain, et al.
Published: (2009)

Analysis of graphic calculator strategy using cognitive load theory
by: Mohd Tajudin, Nor'ain, et al.
Published: (2007)

Dispersion interactions from a local polarizability model
by: Vydrov, Oleg A., et al.
Published: (2011)

Cation polarizability from first-principles: Sn2+
by: Bernasconi, L, et al.
Published: (2001)

Predicting electronic structure properties of transition metal complexes with neural networks
by: Janet, Jon Paul, et al.
Published: (2021)

Depolymerization Pathways for Branching Lignin Spirodienone Units Revealed with ab Initio Steered Molecular Dynamics
by: Mar, Brendan D., et al.
Published: (2017)

When Is Ligand pK[subscript a] a Good Descriptor for Catalyst Energetics? In Search of Optimal CO₂ Hydration Catalysts
by: Kim, Jeong Yun, et al.
Published: (2020)

Ligand-Field-Dependent Behavior of Meta-GGA Exchange in Transition-Metal Complex Spin-State Ordering
by: Ioannidis, Efthymios Ioannis, et al.
Published: (2018)

Effective transport properties of random composites: Continuum calculations versus mapping to a network
by: Chen, Ying, et al.
Published: (2010)

Physical chemistry: When molecules don't rebound.
by: Brouard, M
Published: (2008)

An ontology and semantic web service for quantum chemistry calculations
by: Krdzavac, Nenad, et al.
Published: (2021)