Beyond static structures: Putting forth REMD as a tool to solve problems in computational organic chemistry

Petraglia, Riccardo; Nicolaı̈, Adrien; Wodrich, Matthew D.; Ceriotti, Michele; Corminbœuf, Clémence

doi:10.1002/jcc.24025

Cited by 37 publications

(60 citation statements)

References 144 publications

(182 reference statements)

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“…The geometrical conformations of both 1. trans and 1. cis , were determined by replica-exchange molecular dynamic (REMD) computations performed at the density functional tight binding (DFTB) level (REMD@DFTB). 44 Several minima were identified and optimized statically at the density functional theory level (see ESI for details†). The lowest-lying structures revealed that when the azobenzene is in its extended trans conformation ( 1. trans ), the bithiophene unit is forced to twist out of coplanarity with a dihedral angle ( θ ) of 55° (Fig.…”

Section: Resultsmentioning

confidence: 99%

Photochromic Torsional Switch (PTS): a light-driven actuator for the dynamic tuning of π-conjugation extension

et al. 2017

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Section: Resultsmentioning

confidence: 99%

Photochromic Torsional Switch (PTS): a light-driven actuator for the dynamic tuning of π-conjugation extension

et al. 2017

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“…If a move is rejected, both ensembles are restored to their initial state. The i-PI implementation of replica exchange has already been used to sample organic chemical reactions and conformational transitions with den-sity functional tight binding [33]. Here, we provide a simple demonstration that illustrates the power of this approach using both classical and path integral REMD.…”

Section: Replica Exchange Molecular Dynamicsmentioning

confidence: 92%

“…• replica exchange MD (R. Petraglia, R. Meissner, M. Ceriotti) [33]; accelerated convergence of averages by performing Monte Carlo exchanges of configurations between parallel calculations…”

Section: Program Featuresmentioning

confidence: 99%

i-PI 2.0: A universal force engine for advanced molecular simulations

Kapil

Rossi

Maršálek

et al. 2019

Computer Physics Communications

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Progress in the atomic-scale modelling of matter over the past decade has been tremendous. This progress has been brought about by improvements in methods for evaluating interatomic forces that work by either solving the electronic structure problem explicitly, or by computing accurate approximations of the solution and by the development of techniques that use the Born-Oppenheimer (BO) forces to move the atoms on the BO potential energy surface. As a consequence of these developments it is now possible to identify stable or metastable states, to sample configurations consistent with the appropriate thermodynamic ensemble, and to estimate the kinetics of reactions and phase transitions. All too often, however, progress is slowed down by the bottleneck associated with implementing new optimization algorithms and/or sampling techniques into the many existing electronic-structure and empirical-potential codes. To address this problem, we are thus releasing a new version of the i-PI software. This piece of software is an easily extensible framework for implementing advanced atomistic simulation techniques using interatomic potentials and forces calculated by an external driver code. While the original version of the code[1] was developed with a focus on path integral molecular dynamics techniques, this second release of i-PI not only includes several new advanced path integral methods, but also offers other classes of algorithms. In other words, i-PI is moving towards becoming a universal force engine that is both modular and tightly coupled to the driver codes that evaluate the potential energy surface and its derivatives.

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“…[ 43–45 ] The efficiency of DFTB‐MD for large systems has been greatly improved by combination with fragment molecular orbital [ 46–49 ] or divide‐and‐conquer (DC) techniques. [ 50,51 ] Enhanced sampling methods have been recently applied to DFTB‐MD, resulting in novel DFTB‐REMD, [ 52 ] DFTB‐REUS, [ 53,54 ] and DFTB‐MetaD methods. [ 55,56 ]…”

Section: Introductionmentioning

confidence: 99%

Hierarchical parallelization of divide‐and‐conquer density functional tight‐binding molecular dynamics and metadynamics simulations

Nishimura

Nakai

2020

J Comput Chem

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Massively parallel divide‐and‐conquer density functional tight‐binding (DC‐DFTB) molecular dynamics and metadynamics simulations are efficient approaches for describing various chemical reactions and dynamic processes of large complex systems via quantum mechanics. In this study, DC‐DFTB simulations were combined with multi‐replica techniques. Specifically, multiple walkers metadynamics, replica exchange molecular dynamics, and parallel tempering metadynamics methods were implemented hierarchically into the in‐house Dcdftbmd program. Test simulations in an aqueous phase of the internal rotation of formamide and conformational changes of dialanine showed that the newly developed extensions increase the sampling efficiency and the exploration capabilities in DC‐DFTB configuration space.

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Beyond static structures: Putting forth REMD as a tool to solve problems in computational organic chemistry

Cited by 37 publications

References 144 publications

Photochromic Torsional Switch (PTS): a light-driven actuator for the dynamic tuning of π-conjugation extension

Photochromic Torsional Switch (PTS): a light-driven actuator for the dynamic tuning of π-conjugation extension

i-PI 2.0: A universal force engine for advanced molecular simulations

Hierarchical parallelization of divide‐and‐conquer density functional tight‐binding molecular dynamics and metadynamics simulations

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