D. V. Minakov scite author profile

D. V. Minakov

4Publications

76Citation Statements Received

52Citation Statements Given

How they've been cited

207

How they cite others

280

Affiliations

Joint Institute for High Temperatures, Moscow Institute of Physics and Technology, Institute of Problems of Chemical Physics

Publications

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Quantum molecular dynamics simulation of shock-wave experiments in aluminum

Minakov¹,

Levashov²,

Khishchenko³

et al. 2014

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We present quantum molecular dynamics calculations of principal, porous, and double shock Hugoniots, release isentropes, and sound velocity behind the shock front for aluminum. A comprehensive analysis of available shock-wave data is performed; the agreement and discrepancies of simulation results with measurements are discussed. Special attention is paid to the melting region of aluminum along the principal Hugoniot; the boundaries of the melting zone are estimated using the self-diffusion coefficient. Also, we make a comparison with a high-quality multiphase equation of state for aluminum. Independent semiempirical and first-principle models are very close to each other in caloric variables (pressure, density, particle velocity, etc.) but the equation of state gives higher temperature on the principal Hugoniot and release isentropes than ab initio calculations. Thus, the quantum molecular dynamics method can be used for calibration of semiempirical equations of state in case of lack of experimental data.

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Pseudopotential and full-electron DFT calculations of thermodynamic properties of electrons in metals and semiempirical equations of state

Levashov

Sin'ko

Smirnov

et al. 2010

J. Phys.: Condens. Matter

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In the present work, we compare the thermal contribution of electrons to thermodynamic functions of metals in different models at high densities and electron temperatures. One of the theoretical approaches, the full-potential linear-muffin-tin-orbital method, treats all electrons in the framework of density functional theory (DFT). The other approach, VASP, uses projector-augmented-wave pseudopotentials for the core electrons and considers the valent electrons also in the context of DFT. We analyze the limitations of the pseudopotential approach and compare the DFT results with a finite-temperature Thomas-Fermi model and two semiempirical equations of state.

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Melting curves of metals with excited electrons in the quasiharmonic approximation

Minakov

Levashov

2015

Phys. Rev. B

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Ab initio inspection of thermophysical experiments for molybdenum near melting

2018

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D. V. Minakov

Quantum molecular dynamics simulation of shock-wave experiments in aluminum

Pseudopotential and full-electron DFT calculations of thermodynamic properties of electrons in metals and semiempirical equations of state

Melting curves of metals with excited electrons in the quasiharmonic approximation

Ab initio inspection of thermophysical experiments for molybdenum near melting

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