The ReaxFF reactive force-field: development, applications and future directions

Senftle, Thomas P.; Hong, Sungwook; Islam, Mahbubul; Kylasa, Sudhir B.; Zheng, Yongping; Shin, Yun Kyung; Junkermeier, Chad E.; Engel‐Herbert, Roman; Janik, Michael J.; Aktulga, Hasan Metin; Verstraelen, Toon; Grama, Ananth; Duin, Adri C. T. van

doi:10.1038/npjcompumats.2015.11

Cited by 1,430 publications

(1,139 citation statements)

References 164 publications

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“…Modelling chemical reactivity is beyond the capabilities of classical MD simulations; however, techniques which allow this to be studied have been developed and applied to study lubricant additives. One promising technique is the use of "reactive" force-fields, such as ReaxFF [278] which can approximate chemical reactivity in classical MD simulations through so-called bond order terms [279]. Liang et al [280] gave a general overview of the different types of reactive force-field available in 2013.…”

Section: Linking MD To Smaller Scalesmentioning

confidence: 99%

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

2018

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Nonequilibrium molecular dynamics (NEMD) simulations have provided unique insights into the nanoscale behaviour of lubricants under shear. This review discusses the early history of NEMD and its progression from a tool to corroborate theories of the liquid state, to an instrument that can directly evaluate important fluid properties, towards a potential design tool in tribology. The key methodological advances which have allowed this evolution are also highlighted. This is followed by a summary of bulk and confined NEMD simulations of liquid lubricants and lubricant additives, as they have progressed from simple atomic fluids to ever more complex, realistic molecules. The future outlook of NEMD in tribology, including the inclusion of chemical reactivity for additives, and coupling to continuum methods for large systems, is also briefly discussed.

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Section: Linking MD To Smaller Scalesmentioning

confidence: 99%

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

2018

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“…A full description of all ReaxFF potential functions can be found elsewhere [34]. ReaxFF has different versions dedicated to different materials ranging between polymer, metals, glass, and ceramics [35]. ReaxFF parameter sets developed by Liu et al [27] for polymer and energetic materials are used for Kevlar ® .…”

Section: Force Fieldmentioning

confidence: 99%

Molecular Dynamics Modeling of the Effect of Axial and Transverse Compression on the Residual Tensile Properties of Ballistic Fiber

Chowdhury

Sockalingam

Gillespie

2017

Fibers

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Ballistic impact induces multiaxial loading on Kevlar ® and polyethylene fibers used in protective armor systems. The influence of multiaxial loading on fiber failure is not well understood. Experiments show reduction in the tensile strength of these fibers after axial and transverse compression. In this paper, we use molecular dynamics (MD) simulations to explain and develop a fundamental understanding of this experimental observation since the property reduction mechanism evolves from the atomistic level. An all-atom MD method is used where bonded and non-bonded atomic interactions are described through a state-of-the-art reactive force field. Monotonic tension simulations in three principal directions of the models are conducted to determine the anisotropic elastic and strength properties. Then the models are subjected to multi-axial loads-axial compression, followed by axial tension and transverse compression, followed by axial tension. MD simulation results indicate that pre-compression distorts the crystal structure, inducing preloading of the covalent bonds and resulting in lower tensile properties.

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“…Later, EEM was replaced by the original QEq model in the LAMMPS and PuReMD codes [17]. With the new ReaxPQ, we now calculate all electrostatic interactions using finite-sized charge distributions.…”

Section: Polarizable Charge Equilibration (Pqeq) Methodsmentioning

confidence: 99%

“…The parallel XRMD code has achieved unprecedented scalability and orders-of-magnitude improvement of the time-to-solution over the previous state-of-the-art based on hybrid message passing + multithreading implementation and various code transformations. Here, it should be noted that the extended Lagrangian method is used in tandem with highly efficient preconditioned conjugate-gradient (PCG) methods [17,18] to achieve a high level of convergence.…”

Section: Introductionmentioning

confidence: 99%

Scalable Reactive Molecular Dynamics Simulations for Computational Synthesis

et al. 2019

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Reactive molecular-dynamics (MD) simulation is a powerful research tool for describing chemical reactions. We eliminate the speed-limiting charge iteration in MD with a novel extended-Lagrangian scheme. The extended-Lagrangian reactive MD (XRMD) code drastically improves energy conservation while substantially reducing time-to-solution. Furthermore, we introduce a new polarizable charge equilibration (PQEq) model to accurately predict atomic charges and polarization. The XRMD code based on hybrid message passing+multithreading achieves a weak-scaling parallel efficiency of 0.977 on 786,432 IBM Blue Gene/Q cores for a 67.6 billion-atom system. The performance is portable to the 2 nd generation Intel Xeon Phi, Knights Landing. Blue Gene/Q simulations for the computational synthesis of materials via novel exfoliation mechanisms for synthesizing atomically thin transition metal dichalcogenide layers, which will dominate nanomaterials science in this century. KEYWORDS

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The ReaxFF reactive force-field: development, applications and future directions

Cited by 1,430 publications

References 164 publications

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

Molecular Dynamics Modeling of the Effect of Axial and Transverse Compression on the Residual Tensile Properties of Ballistic Fiber

Scalable Reactive Molecular Dynamics Simulations for Computational Synthesis

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