Chemical accuracy in modeling halide ion hydration from many-body representations

Paesani, Francesco; Bajaj, Pushp; Riera, Marc

doi:10.1080/23746149.2019.1631212

Cited by 42 publications

(53 citation statements)

References 154 publications

(186 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These potential energy functions, termed MB-nrg (for "many-body energy"), employ the same underlying functional forms for the intermolecular many-body interactions as MB-pol. The first MB-nrg models have been devised to describe the interactions of water with monoatomic ions [57][58][59] and, more recently, to describe CO2/water and CH4/water mixtures. 60,61 Similarly to MB-pol, the MBnrg potential energy functions have been successfully used in studies across phases from clusters [62][63][64][65][66][67] to bulk mixtures.…”

Section: Introductionmentioning

confidence: 99%

Highly Accurate Many-Body Potentials for Simulations of N₂O₅ in Water: Benchmarks, Development, and Validation

Cruzeiro

Lambros

Riera

et al. 2021

J. Chem. Theory Comput.

Self Cite

View full text Add to dashboard Cite

Dinitrogen pentoxide (N2O5) is an important intermediate in the atmospheric chemistry of nitrogen oxides.Although there has been much research, the processes that govern the physical interactions between N2O5 and water are still not fully understood at a molecular level. Gaining quantitative insight from computer simulations requires going beyond the accuracy of classical force fields, while accessing length scales and time scales that are out of reach for high-level quantum chemical approaches. To this end we present the development of MB-nrg many-body potential energy functions for simulations of N2O5 in water. This MB-nrg model is based on electronic structure calculations at the coupled cluster level of theory and is compatible with the successful MB-pol model for water. It provides a physically correct description of long-range many-body interactions in combination with an explicit representation of up to three-body short-range interactions in terms of multidimensional permutationally invariant polynomials. In order to further investigate the importance of the underlying interactions in the model, a TTM-nrg model was also devised. TTM-nrg is a more simplistic representation that contains only two-body short-range interactions represented through Born-Mayer functions. In this work an active learning approach was employed to efficiently build representative training sets of monomer, dimer and trimer structures, and benchmarks are presented to determine the accuracy of our new models in comparison to a range of density functional theory methods. By assessing binding curves, distortion energies of N2O5, and interaction energies in clusters of N2O5 and water, we evaluate the importance of two-body and three-body short-range potentials. The results demonstrate that our MB-nrg model has high accuracy with respect to the coupled cluster reference, outperforms current density functional theory models, and thus enables highly accurate simulations of N2O5 in aqueous environments. File list (2)download file view on ChemRxiv paper_n2o5.pdf (1.37 MiB) download file view on ChemRxiv paper_n2o5_si.pdf (731.31 KiB)

show abstract

Section: Introductionmentioning

confidence: 99%

Highly Accurate Many-Body Potentials for Simulations of N₂O₅ in Water: Benchmarks, Development, and Validation

Cruzeiro

Lambros

Riera

et al. 2021

J. Chem. Theory Comput.

Self Cite

View full text Add to dashboard Cite

show abstract

“…Finally, MB PESs for halides in water have recently become available. 36 Perhaps simple methods as introduced herein could be useful in understanding nuclear quantum effects on aqueous ion solvation.…”

Section: Discussionmentioning

confidence: 99%

Temperature and Nuclear Quantum Effects on the Stretching Modes of the Water Hexamer

Samala

Agmon

2020

J. Phys. Chem. A

View full text Add to dashboard Cite

The water hexamer has many low-lying isomers, e.g., ring, book, cage, and prism, shifting from two- to three-dimensional structures. We show that this dimensionality change is accompanied by a drop in the quantum nature of the cluster, as manifested in the red shift of the quantal OH stretching modes as compared with their classical counterparts. We obtain this “nuclear quantum effect” (NQE) as the mean deviation between the OH stretch frequencies from velocity autocorrelation Fourier transforms from classical trajectories on a high-level water potential (MB-pol) as compared with scaled harmonic frequencies from high-level quantum chemistry calculations. With a universal scaling factor, the predicted OH frequencies agree with experiment to a mean absolute deviation ≤10 cm –1 , which allows unequivocal isomer assignments. By assuming temperature-independent NQEs, we produce the temperature dependence of the cage isomer OH stretch spectrum below 70 K, where it is the dominant structure. All bands widen and blue-shift with increasing temperature, most conspicuously the reddest mode, which thus constitutes a “vibrational thermometer”.

show abstract

“…[124][125][126] Because it is currently not possible to perform CM5 and XDM calculations at the DF-FNO-CCSD(T) level of theory, in order to guarantee the same representations of V pol , V 2B disp , and V elec for the two sets of TTM-nrg and MB-nrg PEFs, the CM5 and XDM calculations for all MB-PEFs were carried out with the ωB97M-V functional since it was shown to consistently provide the closest agreement with CCSD(T) data for various molecular interactions. 57,93,96,[138][139][140][141] Both the CM5 and XDM calculations were carried out with Q-Chem v5.1 121 using the aug-cc-pVTZ 137 basis set. All 1B and 2B energies were calculated using Psi4 122 at the corresponding QM level of theory, including counterpoise correction for the BSSE.…”

Section: Example: Ttm-nrg and Mb-nrg Pefs For Ammoniamentioning

confidence: 99%

“…2 and 5 assess the ability of the TTM-nrg and MB-nrg PEFs to reproduce 1B and 2B energies that were the target of the training process, one of the greatest challenges for ML PEFs is to preserve the same accuracy for many-body energies and/or molecular systems that are not included in the training sets. Combining explicit data-driven representations of short-range low-order interactions with implicit (mean-field-like) many-body representations of high-order and long-range interactions, it has been shown that the MB-pol PEF [58][59][60][61]142 for water as well as the MB-nrg PEFs for ions in water 92,95,107,141 and various molecular fluids 97,98 are able to correctly reproduce each individual term of the MBE of Eq. 1.…”

Section: Many-body Energies In Ammonia Clustersmentioning

confidence: 99%

MB-Fit: Software Infrastructure for Data-Driven Many-Body Potential Energy Functions

Bull-Vulpe

Riera

Goetz

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Many-body potential energy functions (MB-PEFs), which integrate data-driven representations of many-body short-range quantum mechanical interactions with physics-based representations of many-body polarization and long-range interactions, have recently been shown to provide high accuracy in the description of molecular interactions, from the gas to the condensed phase. Here, we present MB-Fit, a software infrastructure for the automated development of MB-PEFs for generic molecules within the TTM-nrg ("Thole-type model energy") and MB-nrg ("many-body energy") theoretical frameworks. Besides providing all the necessary computational tools for generating TTM-nrg and MB-nrg PEFs, MB-Fit provides a seamless interface with the MBX software, a many-body energy/force calculator for computer simulations. Given the demonstrated accuracy of the MB-PEFs, we believe that MB-Fit will enable routine, predictive computer simulations of generic (small) molecules in the gas, liquid, and solid phases, including, but not limited to, the modeling of isomeric equilibria in molecular clusters, solvation processes, molecular crystals, and phase diagrams.

show abstract

Chemical accuracy in modeling halide ion hydration from many-body representations

Cited by 42 publications

References 154 publications

Highly Accurate Many-Body Potentials for Simulations of N₂O₅ in Water: Benchmarks, Development, and Validation

Highly Accurate Many-Body Potentials for Simulations of N₂O₅ in Water: Benchmarks, Development, and Validation

Temperature and Nuclear Quantum Effects on the Stretching Modes of the Water Hexamer

MB-Fit: Software Infrastructure for Data-Driven Many-Body Potential Energy Functions

Contact Info

Product

Resources

About

Chemical accuracy in modeling halide ion hydration from many-body representations

Cited by 42 publications

References 154 publications

Highly Accurate Many-Body Potentials for Simulations of N2O5 in Water: Benchmarks, Development, and Validation

Highly Accurate Many-Body Potentials for Simulations of N2O5 in Water: Benchmarks, Development, and Validation

Temperature and Nuclear Quantum Effects on the Stretching Modes of the Water Hexamer

MB-Fit: Software Infrastructure for Data-Driven Many-Body Potential Energy Functions

Contact Info

Product

Resources

About

Highly Accurate Many-Body Potentials for Simulations of N₂O₅ in Water: Benchmarks, Development, and Validation

Highly Accurate Many-Body Potentials for Simulations of N₂O₅ in Water: Benchmarks, Development, and Validation