Recent Advances for Improving the Accuracy, Transferability, and Efficiency of Reactive Force Fields

Leven, Itai; Hao, Hongxia; Tan, Songchen; Guan, Xingyi; Penrod, Katheryn Anne; Akbarian, Dooman; Evangelisti, Benjamin; Hossain, Md Jamil; Islam, Mahbubul; Koski, Jason; Moore, Stan Gerald; Aktulga, Hasan Metin; Duin, Adri C. T. van; Head‐Gordon, Teresa

doi:10.1021/acs.jctc.1c00118

Cited by 50 publications

(43 citation statements)

References 64 publications

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“…46,47,48 . In this work we have utilized a reactive force eld model of water, ReaxFF/C-GeM 49,50 , that explicitly models coarse-grained electrons 45 , and yet can handle the relatively large sub-micron droplets simulated over tens of nanoseconds that we have examined here that is not accessible to ab initio molecular dynamics. Figure 1B veri es that the Stark shift trends are very well captured by the ReaxFF/C-GeM model, which is relevant for not only the validation of the simulation model, but plays an important interpretative role in analyzing the electric eld for large water droplets in terms of electron density, protonation states, and ion effects at the air-water interface.…”

Section: Resultsmentioning

confidence: 99%

“…The cubic box was set to be (80 Å) 3 , (120 Å) 3 , (160 Å) 3 , and (200 Å) 3 for R40, R60, and R80 droplets, respectively. The systems were then transferred into a recent implementation in LAMMPS 50 , where the reactive force eld ReaxFF/CGeM model has been implemented and the MD trajectories were conducted. After 500 ps of equilibration, we collected snapshots every 1 ps across a 400 ps production run to obtain the electric eld.…”

Section: Methodsmentioning

confidence: 99%

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Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Hao

Leven

Head‐Gordon

2021

Preprint

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Reaction rates of common organic reactions have been reported to increase by one to six orders of magnitude in aqueous microdroplets compared to bulk solution, but the reasons for the rate acceleration are poorly understood. We investigate the role of electric fields at water droplet surfaces that might explain the promotion of unusual reactive chemistry, along with changes in electric field profiles as a function of excess charge to model the electrospray fragmentation process. We find that electric field alignments along free O-H bonds at the surface yield field strength distributions that are ~30 MV/cm larger on average than that found for O-H bonds in the interior of the water droplet, consistent with greater surface reactivity. We emphasize the importance of both nuclear and electronic effects at the surface, and the non-linear coupling of intramolecular solute polarization with intermolecular solvent modes, as a necessary feature for predicting the higher field strengths at water droplet surfaces.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Hao

Leven

Head‐Gordon

2021

Preprint

Self Cite

View full text Add to dashboard Cite

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“…The cubic box was set to be (120 Å) 3 , (160 Å) 3 , and (200 Å) 3 for R40, R60, and R80 droplets, respectively. The systems were then transferred into a recent implementation in LAMMPS 39 , where the reactive force field ReaxFF/CGeM model has been implemented and the MD trajectories were conducted. After 500 ps of equilibration, we collected snapshots every 1 ps across a 400 ps to 1 ns production run to obtain the electric field.…”

Section: Methodsmentioning

confidence: 99%

“…In this work we have utilized a reactive force field model of water, ReaxFF/C-GeM 38 , 39 , that explicitly models coarse-grained electrons and thus the internal electronic charge distribution of the water molecule 40 , and yet can well describe the structural organization and dynamics of water for relatively large sub-micron droplets over tens to hundreds of nanoseconds, size and timescales that are not accessible with ab initio molecular dynamics (AIMD). Here we use the model to simulate the electric fields of large droplets of 80–160 Å in diameter to characterize their field strengths at the air-water surface, and to evaluate the electric fields for different charge states of the water droplets with an excess of Na + ions, Cl − ions, H 3 O + ions, OH − ions and Na + /Cl − ion mixtures.…”

Section: Introductionmentioning

confidence: 99%

Can electric fields drive chemistry for an aqueous microdroplet?

2022

Self Cite

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Reaction rates of common organic reactions have been reported to increase by one to six orders of magnitude in aqueous microdroplets compared to bulk solution, but the reasons for the rate acceleration are poorly understood. Using a coarse-grained electron model that describes structural organization and electron densities for water droplets without the expense of ab initio methods, we investigate the electric field distributions at the air-water interface to understand the origin of surface reactivity. We find that electric field alignments along free O–H bonds at the surface are ~16 MV/cm larger on average than that found for O–H bonds in the interior of the water droplet. Furthermore, electric field distributions can be an order of magnitude larger than the average due to non-linear coupling of intramolecular solvent polarization with intermolecular solvent modes which may contribute to even greater surface reactivity for weakening or breaking chemical bonds at the droplet surface.

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“…18 The electrostatic interactions can be calculated by the electronegativity equilibration method (EEM) 37,38 when performing standard ReaxFF, however, it includes inadequacies such as long-range charge transfer, noninteger molecular charges at large separations, out-of-plane polarization, and so forth. To impede unphysical long-range charge transfer, the atom-condensed Kohn-Sham (ACKS2) 39 approach provides an extension to the EEM that improves the atom-in-molecu description e. 40 In eReaxFF, the electron and electron-hole can modify only the over-coordination, penalty, under-coordination, and lone pair energy stability, while ACKS2 describes the electrostatic interactions.…”

Section: Introductionmentioning

confidence: 99%

Valence energy correction for electron reactive force field

Bertolini

Jacob

2022

J Comput Chem

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Reactive force fields (ReaxFF) are a classical method to describe material properties based on a bond‐order formalism, that allows bond dissociation and consequently investigations of reactive systems. Semiclassical treatment of electrons was introduced within ReaxFF simulations, better known as electron reactive force fields (eReaxFF), to explicitly treat electrons as spherical Gaussian waves. In the original version of eReaxFF, the electrons and electron–holes can lead to changes in both the bond energy and the Coulomb energy of the system. In the present study, the method was modified to allow an electron to modify the valence energy, therefore, permitting that the electron's presence modifies the three‐body interactions, affecting the angle among three atoms. When a reaction path involving electron transfer is more sensitive to the geometric configuration of the molecules, corrections in the angular structure in the presence of electrons become more relevant; in this case, bond dissociation may not be enough to describe a reaction path. Consequently, the application of the extended eReaxFF method developed in this work should provide an improved description of a reaction path. As a first demonstration this semiclassical force field was parametrized for hydrogen and oxygen interactions, including water and water's ions. With the modified methodology both the overall accuracy of the force field but also the description of the angles within the molecules in presence of electrons could be improved.

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Recent Advances for Improving the Accuracy, Transferability, and Efficiency of Reactive Force Fields

Cited by 50 publications

References 64 publications

Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Can Electric Fields Drive Chemistry for an Aqueous Microdroplet?

Can electric fields drive chemistry for an aqueous microdroplet?

Valence energy correction for electron reactive force field

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