Thermal and Nuclear Quantum Effects at the Antiferroelectric to Paraelectric Phase Transition in KOH and KOD Crystals

Fallacara, Erika; Depondt, Philippe; Huppert, Simon; Ceotto, Michele; Finocchi, Fabio

doi:10.1021/acs.jpcc.1c06953

Cited by 5 publications

(4 citation statements)

References 44 publications

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“…The efficiency and massive parallelization capabilities of the newly introduced platform now allows the inclusion of explicit nuclear quantum effects in very large systems. This should be particularly relevant for simulations in extreme conditions of pressure or temperature where NQEs can be massive ,,, or to investigate disorder effects in solids for which NQEs can be determinant and large supercells required. − Importantly, being able to simulate quantum nuclei enables the study of isotope effects that are simply not reachable using classical MD. , Finally, it opens up the possibility of investigating quantitatively the importance of NQEs in biological processes , and the subtleties of hydrogen-bonded systems . While the methods for quantum MD are now readily available in Tinker-HP, it will be necessary to reparametrize some of the force fields to avoid double counting of implicit and explicit NQEs, as was shown in the case of Q-AMOEBA for water .…”

Section: Discussionmentioning

confidence: 99%

Routine Molecular Dynamics Simulations Including Nuclear Quantum Effects: From Force Fields to Machine Learning Potentials

Plé¹,

Mauger²,

Adjoua³

et al. 2023

J. Chem. Theory Comput.

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We report the implementation of a multi-CPU and multi-GPU massively parallel platform dedicated to the explicit inclusion of nuclear quantum effects (NQEs) in the Tinker-HP molecular dynamics (MD) package. The platform, denoted Quantum-HP, exploits two simulation strategies: the Ring-Polymer Molecular Dynamics (RPMD) that provides exact structural properties at the cost of a MD simulation in an extended space of multiple replicas and the adaptive Quantum Thermal Bath (adQTB) that imposes the quantum distribution of energy on a classical system via a generalized Langevin thermostat and provides computationally affordable and accurate (though approximate) NQEs. We discuss some implementation details, efficient numerical schemes, and parallelization strategies and quickly review the GPU acceleration of our code. Our implementation allows an efficient inclusion of NQEs in MD simulations for very large systems, as demonstrated by scaling tests on water boxes with more than 200,000 atoms (simulated using the AMOEBA polarizable force field). We test the compatibility of the approach with Tinker-HP's recently introduced Deep-HP machine learning potentials module by computing water properties using the DeePMD potential with adQTB thermostatting. Finally, we show that the platform is also compatible with the alchemical free energy estimation capabilities of Tinker-HP and fast enough to perform simulations. Therefore, we study how NQEs affect the hydration free energy of small molecules solvated with the recently developed Q-AMOEBA water force field. Overall, the Quantum-HP platform allows users to perform routine quantum MD simulations of large condensed-phase systems and will help to shed new light on the quantum nature of important interactions in biological matter.

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Section: Discussionmentioning

confidence: 99%

Routine Molecular Dynamics Simulations Including Nuclear Quantum Effects: From Force Fields to Machine Learning Potentials

Plé¹,

Mauger²,

Adjoua³

et al. 2023

J. Chem. Theory Comput.

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“…Nuclear quantum effects, however, also often come into play at ambient conditions, typically when the thermal energy of chemical bonds in molecules is comparable or smaller than the associated vibrational ZPE or when characteristic interatomic distances in the system are comparable to the de Broglie wavelength of the nuclei. These conditions are met, in particular, in systems containing light atoms and most notably hydrogen [4,5], which is a ubiquitous constituent of inorganic compounds and a basic element in biological systems. Thus, nuclear quantum effects influence, for example, the stability of crystal polymorphs of pharmaceutical interest, the spectroscopy of ice and water, or enzymatic reactions in living organisms [6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Simulation of Nuclear Quantum Effects in Condensed Matter Systems via Quantum Baths

Huppert

Finocchi

2022

Applied Sciences

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This paper reviews methods that aim at simulating nuclear quantum effects (NQEs) using generalized thermal baths. Generalized (or quantum) baths simulate statistical quantum features, and in particular zero-point energy effects, through non-Markovian stochastic dynamics. They make use of generalized Langevin Equations (GLEs), in which the quantum Bose–Einstein energy distribution is enforced by tuning the random and friction forces, while the system degrees of freedom remain classical. Although these baths have been formally justified only for harmonic oscillators, they perform well for several systems, while keeping the cost of the simulations comparable to the classical ones. We review the formal properties and main characteristics of classical and quantum GLEs, in relation with the fluctuation–dissipation theorems. Then, we describe the quantum thermostat and quantum thermal bath, the two generalized baths currently most used, providing several examples of applications for condensed matter systems, including the calculation of vibrational spectra. The most important drawback of these methods, zero-point energy leakage, is discussed in detail with the help of model systems, and a recently proposed scheme to monitor and mitigate or eliminate it—the adaptive quantum thermal bath—is summarised. This approach considerably extends the domain of application of generalized baths, leading, for instance, to the successful simulation of liquid water, where a subtle interplay of NQEs is at play. The paper concludes by overviewing further development opportunities and open challenges of generalized baths.

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“…Many other such examples exist: for instance KOH and KOD [9] exhibit a 30K temperature di↵erence for a structural phase transition at ambient pressure; NaOH is paraelectric without change as temperature is decreased, while NaOD undergoes a phase transition to an antiferroelectric structure at 150K [10][11][12][13]. SrTiO 3 also shows isotopic e↵ects [14] upon O 16 -O 18 substitution.…”

Section: Introductionmentioning

confidence: 99%

The quantum taste of hydrogen

2022

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Electronic properties of materials are dominated by quantum effects, but nuclei, being much heavier, are usually treated as classical particles. This approximation, although tremendously convenient, is not always valid, even in close to ambient pressure and temperature conditions, especially when light nuclei such as hydrogen are involved. Zero point energy and proton tunneling can be relevant. Isotopic effects, obtained by replacing hydrogen with deuterium, are observed experimentally and are a clear indication of Nuclear Quantum Effects (NQE) since mean values obtained through classical statistical physics do not depend on mass. Introducing NQEs into simulations at an acceptable computational cost raises fundamental questions and yields subtle and unexpected results.

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Thermal and Nuclear Quantum Effects at the Antiferroelectric to Paraelectric Phase Transition in KOH and KOD Crystals

Cited by 5 publications

References 44 publications

Routine Molecular Dynamics Simulations Including Nuclear Quantum Effects: From Force Fields to Machine Learning Potentials

Routine Molecular Dynamics Simulations Including Nuclear Quantum Effects: From Force Fields to Machine Learning Potentials

Simulation of Nuclear Quantum Effects in Condensed Matter Systems via Quantum Baths

The quantum taste of hydrogen

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