General Many-Body Framework for Data-Driven Potentials with Arbitrary Quantum Mechanical Accuracy: Water as a Case Study

Lambros, Eleftherios; Dasgupta, Saswata; Palos, Etienne; Swee, Steven; Hu, Jie; Paesani, Francesco

doi:10.1021/acs.jctc.1c00541

Cited by 35 publications

(42 citation statements)

References 164 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Building upon the demonstrated accuracy of the MB-pol PEF for water 78 – 81 and following the same theoretical/computational approach employed in the development of DFT-based many-body PEFs 51 , 90 , 107 , we used Eq. ( 4 ) to develop a data-driven many-body PEF, MB-SCAN(DC), that consistently reproduces each term of the MBE for water calculated using the DC-SCAN functional.…”

Section: Methodsmentioning

confidence: 99%

“…( 4 ) is represented by the Partridge−Schwenke PEF 108 , while ϵ 2B and ϵ 3B are represented by terms describing permanent electrostatics, dispersion energy, and induction, which are combined with short-range permutationally invariant polynomials (PIPs) 109 fitted to reproduce 2B and 3B energies calculated with DC-SCAN for the same training sets of water dimers and trimers used in the development of MB-pol 79 , 80 . A detailed description of the theoretical and computational framework adopted in the development of data-driven many-body PEFs for water can be found in the original references 51 , 79 , 80 , 90 , 107 . It should be noted that, since our many-body PEFs directly target the underlying molecular interactions, differences in the representation of the 1-body (1B) term of Eq.…”

Section: Methodsmentioning

confidence: 99%

“…It should be noted that, since our many-body PEFs directly target the underlying molecular interactions, differences in the representation of the 1-body (1B) term of Eq. ( 5 ) have been found to be negligible for modeling the properties of liquid water 107 and the air/water interface 110 .…”

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

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

et al. 2021

Self Cite

View full text Add to dashboard Cite

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.

show abstract

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

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

et al. 2021

Self Cite

View full text Add to dashboard Cite

show abstract

“…Our group has been active for some time developing MLPs using Permutationally Invariant Polynomials (PIPs) 13,[22][23][24][25][26][27][28][29] for "small molecules"; some early examples include CH + 5 and H 5 O + 2 , malonaldehyde and the 10-atom formic acid dimer. 30 More recently, we have reported PIP PESs for 10-15 atom molecules, listed in Table I using enhancements to the PIP basis.…”

Section: Introductionmentioning

confidence: 99%

The MD17 Datasets from the Perspective of Datasets for Gas-Phase "Small" Molecule Potentials

Bowman,

Conte,

Nandi

et al. 2022

Preprint

View full text Add to dashboard Cite

There has been great progress in developing methods for machine-learned potential energy surfaces. There have also been important assessments of these methods by comparing so-called learning curves on datasets of electronic energies and forces, notably the MD17 database. The dataset for each molecule in this database generally consists of tens of thousands of energies and forces obtained from DFT direct dynamics at 500 K. We contrast the datasets from this database for three "small" molecules, ethanol, malonaldehyde, and glycine, with datasets we have generated with specific targets for the PESs in mind: a rigorous calculation of the zero-point energy and wavefunction, the tunneling splitting in malonaldehyde and in the case of glycine a description of all eight low-lying conformers. We found that the MD17 datasets are too limited for these targets. We also examine recent datasets for several PESs that describe small-molecule but complex chemical reactions. Finally, we introduce a new database,"QM-22", which contains datasets of molecules ranging from 4 to 15 atoms that extend to high energies and a large span of configurations.

show abstract

“…This ML method, introduced for CH + 5 in 2003, 10 is actively used [11][12][13][14] and further developed. 15-17 a) Electronic mail: plh2@cornell.edu b) Electronic mail: apurba.nandi@emory.edu c) Electronic mail: riccardo.conte1@unimi.it d) Electronic mail: q.yu@yale.edu e) Electronic mail: jmbowma@emory.edu PIPs have also been incorporated in Neural Network methods, 6,[18][19][20] , Gaussian Process Regression 21 , and recently to atom-centered Gaussian Process Regression.…”

Section: Introductionmentioning

confidence: 99%

Permutationally invariant polynomial regression for energies and gradients, using reverse differentiation, achieves orders of magnitude speed-up with high precision compared to other machine learning methods

Houston,

Qu,

Nandi

et al. 2021

Preprint

View full text Add to dashboard Cite

Permutationally invariant polynomial (PIP) regression has been used to obtain machine-learned (ML) potential energy surfaces, including analytical gradients, for many molecules and chemical reactions. Recently, the approach has been extended to moderate size molecules and applied to systems up to 15 atoms. The algorithm, including "purification of the basis", is computationally efficient for energies; however, we found that the recent extension to obtain analytical gradients, despite being a remarkable advance over previous methods, could be further improved. Here we report developments to compact further a purified basis and, more significantly, to use the reverse gradient approach to greatly speed up gradient evaluation. We demonstrate this for our recent 4-body water interaction potential. Comparisons of training and testing precision on the MD17 database of energies and gradients (forces) for ethanol against GP-SOAP, ANI, sGDML, PhysNet, KREG, KRR and other methods, which were recently assessed by Dral and co-workers, are given. The PIP fits are as precise as those using these methods, but the PIP computation time for energy and force evaluation is shown to be 10 to 1000 times faster. Finally, a new PIP PES is reported for ethanol based on a more extensive dataset of energies and gradients than in the MD17 database. Diffusion Monte Carlo calculations which fail on MD17-based PESs are successful using the new PES.

show abstract

General Many-Body Framework for Data-Driven Potentials with Arbitrary Quantum Mechanical Accuracy: Water as a Case Study

Cited by 35 publications

References 164 publications

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

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

The MD17 Datasets from the Perspective of Datasets for Gas-Phase "Small" Molecule Potentials

Permutationally invariant polynomial regression for energies and gradients, using reverse differentiation, achieves orders of magnitude speed-up with high precision compared to other machine learning methods

Contact Info

Product

Resources

About