Langevin Dynamics with Spatial Correlations as a Model for Electron-Phonon Coupling

Tamm, Artur; Caro, M.; Caro, A.; Samolyuk, German D.; Klintenberg, Mattias; Correa, Alfredo A.

doi:10.1103/physrevlett.120.185501

Cited by 52 publications

(63 citation statements)

References 36 publications

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“…At sufficiently low energies (v < v F ), the stopping process can be finally described as the interaction with a free-electron gas (FEG) [12,13]. At these intermediate and low ion energies, a series of recent experimental and theoretical studies aim on improving our understanding of the ion-solid interaction [14][15][16], as well as on exploring complex nonequilibrium solid-state physics [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Experimental electronic stopping cross section of transition metals for light ions: Systematics around the stopping maximum

2020

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Electronic stopping cross sections of different transition metals (Nb, Pd, Ta, and Pt) for light ions have been experimentally determined in a wide energy range. We performed relative measurements using different backscattering geometries for protons (from 50 to 5000 keV) and helium (from 80 to 10 000 keV). Data are compared to values from the literature, as well as to the widely used semiempirical (SRIM) and modeling (DPASS) approaches. The magnitude and energy dependence of the deduced stopping power at energies around the Bragg peak, as well as the different trends observed within individual periods, are analyzed with respect to target atomic number and electronic structure. We also compare the observed magnitude of electronic stopping to several different theoretical approaches.

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Section: Introductionmentioning

confidence: 99%

Experimental electronic stopping cross section of transition metals for light ions: Systematics around the stopping maximum

2020

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“…Metallic nanowires have excellent electrical and thermal conductivity, but the size can dramatically affect these two properties. Recently, Tamm et al [63,64] have implemented a new version of the TTM-MD model in which they replace the scalar values of friction and random forces over individual particles with many-body forces that act in a correlated manner over different particles. This generalization allows modeling the electronic subsystem in a metal as a generalized Langevin bath equipped with a concept of locality due to correlation.…”

Section: Summary and Future Outlooksmentioning

confidence: 99%

MeV irradiation of tungsten nanowires: structural modifications

Grossi

Kohanoff

Bringa

2020

Mater. Res. Express

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In this work we use the Two Temperature Model coupled to Molecular Dynamics (TTM-MD) to study swift heavy ion irradiation of W finite nanowires. Au projectiles are considered with energies ranging from 20 to 50 MeV, which correspond to electronic stopping values less than 20 keV nm −1 in the regime where electronic stopping is larger than nuclear stopping. Nanowires with diameters much smaller than the electron mean free path are considered for two different sizes with an aspect ratio ∼3.7 between length and diameter. Nanowires display radiation-induced surface roughening, sputtering yields and the formation of point defects and di-vacancies. For the smallest size, a hole stays opened in the central part of the wire for S e > 12.6 keV nm −1 . W nanofoams, considered as collections of connected nanowires like those simulated here, are expected to behave similarly under irradiation displaying radiation resistance for the electronic stopping range that has been considered. In fact, nanowires larger than tens of nm would be needed for defect accumulation and lack of radiation resistance.

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“…Recently, several theoretical techniques have been developed that go beyond the BO approximation. The simplest technique couples the ions to a Langevin thermostat which models the electron-ion collisions through an additional stochastic Gaussian force added to the equations of motion [11,[16][17][18][19]. While efficient, this phenomenological approach uses a single collision frequency that must be determined a priori.…”

Section: Introductionmentioning

confidence: 99%

An Investigation into the Approximations Used in Wave Packet Molecular Dynamics for the Study of Warm Dense Matter

Angermeier

White

2021

Plasma

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Wave packet molecular dynamics (WPMD) has recently received a lot of attention as a computationally fast tool with which to study dynamical processes in warm dense matter beyond the Born–Oppenheimer approximation. These techniques, typically, employ many approximations to achieve computational efficiency while implementing semi-empirical scaling parameters to retain accuracy. We investigated three of the main approximations ubiquitous to WPMD: a restricted basis set, approximations to exchange, and the lack of correlation. We examined each of these approximations in regard to atomic and molecular hydrogen in addition to a dense hydrogen plasma. We found that the biggest improvement to WPMD comes from combining a two-Gaussian basis with a semi-empirical correction based on the valence-bond wave function. A single parameter scales this correction to match experimental pressures of dense hydrogen. Ultimately, we found that semi-empirical scaling parameters are necessary to correct for the main approximations in WPMD. However, reducing the scaling parameters for more ab-initio terms gives more accurate results and displays the underlying physics more readily.

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Langevin Dynamics with Spatial Correlations as a Model for Electron-Phonon Coupling

Cited by 52 publications

References 36 publications

Experimental electronic stopping cross section of transition metals for light ions: Systematics around the stopping maximum

Experimental electronic stopping cross section of transition metals for light ions: Systematics around the stopping maximum

MeV irradiation of tungsten nanowires: structural modifications

An Investigation into the Approximations Used in Wave Packet Molecular Dynamics for the Study of Warm Dense Matter

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