The influence of the electronic specific heat on swift heavy ion irradiation simulations of silicon

Khara, Galvin S; Murphy, Samuel T.; Daraszewicz, Szymon L.; Duffy, Dorothy M.

doi:10.1088/0953-8984/28/39/395201

Cited by 25 publications

(19 citation statements)

References 57 publications

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“…The thermal conductivity of the lattice is chosen to be λ l = 130 W/mK for simplicity in this calculation. The specific heat of the electron depends on the electron temperature, and we use a linear relation C e = γ T e , where γ = 50 J/m 3 K 2 [41]. We assume electron thermal conductivity in silicon follows the Wiedemann-Franz law, λ e = Lσ T e , where Lσ = 24.4 µW/mK 2 [42].…”

Section: Theoretical Methodsmentioning

confidence: 99%

“…We assume electron thermal conductivity in silicon follows the Wiedemann-Franz law, λ e = Lσ T e , where Lσ = 24.4 µW/mK 2 [42]. Following the methodology in Khara et al, the lattice-electron coupling term is calculated to be G = 2.8 × 10 17 W/m 3 K [41]. The solid-liquid coupling coefficient is chosen W = 10 8 W/m 2 K as the description following Equation (9).…”

Section: Theoretical Methodsmentioning

confidence: 99%

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Femtosecond Laser-Induced Thermal Transport in Silicon with Liquid Cooling Bath

et al. 2019

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Nanostructured regular patterns on silicon surface are made by using femtosecond laser irradiations. This is a novel method that can modify the surface morphology of any large material in an easy, fast, and low-cost way. We irradiate a solid surface with a 400-nm double frequency beam from an 800-nm femtosecond laser, while the solid surface is submerged in a liquid or exposed in air. From the study of multiple-pulses and single-pulse irradiations on silicon, we find the morphologies of nanospikes and capillary waves to follow the same distribution and periodicity. Thermal transport near the solid surface plays an important role in the formation of patterns; a simulation was done to fully understand the mechanism of the pattern formation in single pulse irradiation. The theoretical models include a femtosecond laser pulse function, a two-temperature model (2-T model), and an estimation of interface thermal coupling. The evolution of lattice temperature over time will be calculated first without liquid cooling and then with liquid cooling, which has not been well considered in previous theoretical papers. The lifetime of the capillary wave is found to be longer than the solidification time of the molten silicon only when water cooling is introduced. This allows the capillary wave to be frozen and leaves interesting concentric rings on the silicon surface. The regular nanospikes generated on the silicon surface result from the overlapping capillary waves.

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Section: Theoretical Methodsmentioning

confidence: 99%

Section: Theoretical Methodsmentioning

confidence: 99%

Femtosecond Laser-Induced Thermal Transport in Silicon with Liquid Cooling Bath

et al. 2019

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“…Silicon is a widely studied material in the context of strongly driven phase transitions, both experimentally [1][2][3][4][5][6] and theoretically [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29], where it is found to melt on a subpicosecond timescale at high excitations. Most theoretical studies of nonthermal melting in silicon have employed ab initio simulation methods.…”

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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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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“…In these materials is zero at low because there is insufficient thermal energy to excite electrons across the gap. As is very sensitive to the size of the bandgap, it is necessary to employ a DFT functional that correctly reproduces this feature, as it has been demonstrated that different functionals produce very different degrees of damage in SHI simulations of silicon [37]. Calculating the dependence of for band gap materials is more challenging as ( )is zero in these materials so equation 3.1 diverges.…”

Section: Figure 2: a Schematic Representation Of The Energy Depositiomentioning

confidence: 99%

“…The model was coupled to MD to give an extended version of 2T-MD and used to model SHI irradiation in Ge [68]. As argued above, however, the use of the electron density as an additional parameter is unnecessary, and other studies of SHI irradiation in Si [37], UO2 [69] and SiO2 [70] have omitted it.…”

Section: Shi Irradiationmentioning

confidence: 99%

Modelling radiation effects in solids with two-temperature molecular dynamics

Darkins

Duffy

2018

Computational Materials Science

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The ability to predict the structural modifications of materials resulting from a broad range of irradiation scenarios would have a positive impact on many fields of science and technology. Established techniques for modelling large atomic systems, such as classical molecular dynamics, are limited by the neglect of the electronic degrees of freedom which restricts their application to irradiation events that primarily interact with atomic nuclei. Ab initio methods, on the other hand, include electronic degrees of freedom, but the requisite computational costs restrict their application to relatively small systems. Recent methodological developments aimed at overcoming some of these limitations are based on methods that couple atomistic models to a continuum model for the electronic energy, where energy is exchanged between the nuclei and electrons via electronic stopping and electron-phonon coupling mechanisms. Such two-temperature molecular dynamics models, as they are known, make it practicable to simulate the effects of electronic excitations on systems with millions, or even hundreds of millions, of atoms. They have been used to study laser irradiation of metallic films, swift heavy ion irradiation of metals and semiconductors, and moderately high ion irradiation of metals. In this review we describe the two-temperature molecular dynamics methodology and the various practical considerations required for its implementation. We provide example applications of the model to multiple irradiation scenarios that accommodate electronic excitations. We also describe the challenges of including the effects of the modification of the interatomic interactions, due to the excitation of electrons, in the simulations and how these challenges can be overcome.

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The influence of the electronic specific heat on swift heavy ion irradiation simulations of silicon

Cited by 25 publications

References 57 publications

Femtosecond Laser-Induced Thermal Transport in Silicon with Liquid Cooling Bath

Femtosecond Laser-Induced Thermal Transport in Silicon with Liquid Cooling Bath

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

Modelling radiation effects in solids with two-temperature molecular dynamics

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