Modelling radiation effects in solids with two-temperature molecular dynamics

Darkins, Robert; Duffy, Dorothy M.

doi:10.1016/j.commatsci.2018.02.006

Cited by 35 publications

(29 citation statements)

References 84 publications

(101 reference statements)

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“…This approach has the advantage that the electronic heat capacity may be expressed as a function of the carrier density, and the optical properties of the material are more straightforwardly accounted for by using the carrier density to attenuate the radiation intensity as it passes through the material. However, as previously noted [30], explicitly including a term for the carrier density is superfluous since the carrier density has a one-to-one relationship with the electronic temperature under (quasi)equilibrium conditions. It follows that any function of the carrier density may instead be written as a function of electronic temperature.…”

Section: A Two-temperature Molecular Dynamicsmentioning

confidence: 99%

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Simulating electronically driven structural changes in silicon with two-temperature molecular dynamics

Darkins

Murphy

et al. 2018

Phys. Rev. B

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Radiation can drive the electrons in a material out of thermal equilibrium with the nuclei, producing hot, transient electronic states that modify the interatomic potential energy surface. We present a rigorous formulation of two-temperature molecular dynamics that can accommodate these electronic effects in the form of electronic-temperature-dependent force fields. Such a force field is presented for silicon, which has been constructed to reproduce the ab initio-derived thermodynamics of the diamond phase for electronic temperatures up to 2.5 eV, as well as the structural dynamics observed experimentally under nonequilibrium conditions in the femtosecond regime. This includes nonthermal melting on a subpicosecond timescale to a liquidlike state for electronic temperatures above ∼1 eV. The methods presented in this paper lay a rigorous foundation for the large-scale atomistic modeling of electronically driven structural dynamics with potential applications spanning the entire domain of radiation damage.

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Section: A Two-temperature Molecular Dynamicsmentioning

confidence: 99%

“…However, the cost of these techniques make them unsuitable for studying large length or timescale processes such as ablation and spallation. It is within * r.darkins@ucl.ac.uk this domain of large-scale atomistic modeling of radiation damage that two-temperature molecular dynamics (2T-MD) has prevailed as the method of choice [30].…”

Section: Introductionmentioning

confidence: 99%

Simulating electronically driven structural changes in silicon with two-temperature molecular dynamics

Darkins

Murphy

et al. 2018

Phys. Rev. B

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“…Swift heavy ion irradiated systems apply energy deposition that varies radially in two-dimensions from a central point and decays exponentially in time: the electronic temperature grid in these systems typically extends far from the MD cell in these two dimensions with energy-removing boundaries as well as closed or periodic boundaries in the third dimension. A fuller description of the use of 2T-MD (molecular dynamics with TTM) is given in [13].…”

Section: Two-temperature Modelmentioning

confidence: 99%

“…A number of simulations have been carried out with modified versions of dl poly 4 that have incorporated the above-mentioned TTM functionalities [13]. These can be divided between radiation damage cascades, laser irradiation and swift heavy ion (SHI) irradiation.…”

Section: Applications Of Ttm With DL Polymentioning

confidence: 99%

Domain decomposition of the two-temperature model in DL_POLY_4

Seaton

Todorov

Daraszewicz

et al. 2018

Molecular Simulation

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Including the effects of excited electrons in classical simulations, at the level of the two-temperature model, involves the coupling of a grid-based finite-difference solver for a heat diffusion equation and classical molecular dynamics simulations with an inhomogeneous thermostat. Simulation of large systems requires domain decomposition of both particle-based and grid-based techniques. Starting with the CCP5 flagship code dl poly 4 as the domain-decomposed molecular dynamics code, we devised a method to divide up temperature grids among processor cores in a similar fashion, including the appropriate communications between cores to deal with boundaries between grid divisions. This article gives the outline of how the domain decomposition of the temperature grids was achieved, as well as some example applications of the two-temperature model implementation in dl poly 4.

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“…the one developed by Duffy et al in [8]). The only parameter not present in the Duffy et al version of the TTM we use is the activation time of the electron-phonon coupling (t eph ) which acts to delay by a fraction of picosecond the time at which the electronphonon coupling is activated (Zarkadoula et al set it between 0.2 ps and 1 ps in their works [11,10,18]) and whose use is vivedly recommended [11] and well spread in the community [17,10,18,19]. Experiments [20,21] and MD simulations [2] have showed that the response of Si and Ge materials to particle irradiation is very unalike because of their different thermal properties [4].…”

Section: Introductionmentioning

confidence: 99%

Parametric study of the Two-Temperature Model for Molecular Dynamics simulations of collisions cascades in Si and Ge

Jarrin

Jay

Hémeryck

et al. 2020

Nuclear Instruments and Methods in Physics Research Section B:

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The sensitivity of collision cascades simulations to the Two-Temperature Model main parameters is investigated by performing an extensive statistical study both in Si and Ge materials. The purpose is to identify the parameters of the Two-Temperature Model whose impact is the most significant on the cascades properties and to discuss the physical role of each parameter. We demonstrate that the electronic stopping power and electron phonon coupling have a drastic impact both in Si and Ge but that these two parameters act differently on those two materials due to their distinct thermal properties. We show that the formation of thermal spikes and therefore of amorphous pockets is sensitive to the electronic specific heat. The effects are again very distinct in Si and in Ge. The influence of both the threshold velocity for the stopping power and the electron-phonon coupling activation time are found to be negligible at the considered energies.

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Modelling radiation effects in solids with two-temperature molecular dynamics

Cited by 35 publications

References 84 publications

Simulating electronically driven structural changes in silicon with two-temperature molecular dynamics

Simulating electronically driven structural changes in silicon with two-temperature molecular dynamics

Domain decomposition of the two-temperature model in DL_POLY_4

Parametric study of the Two-Temperature Model for Molecular Dynamics simulations of collisions cascades in Si and Ge

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