Leila Momenzadeh scite author profile

An analytical treatment of decomposition of the phonon thermal conductivity of a crystal with a monatomic unit cell is developed on the basis of a twostage decay of the heat current autocorrelation function observed in molecular dynamics simulations. It is demonstrated that the contributions from the acoustic short-and long-range phonon modes to the total phonon thermal conductivity can be presented in the form of simple kinetic formulas, consisting of products of the heat capacity and the average relaxation time of the considered phonon modes as well as the square of the average phonon velocity. On the basis of molecular dynamics calculations of the heat current autocorrelation function, this treatment allows for a self-consistent numerical evaluation of the aforementioned variables. In addition, the presented analysis allows, within the Debye approximation, for the identification of the temperature range where classical molecular dynamics simulations can be employed for the prediction of phonon thermal transport properties. As a case example, Cu is considered. IntroductionIt is well known that the thermodynamic and transport properties of a crystal lattice can be generally described using the concept of phonons (lattice vibrations or lattice waves) [1][2][3]. For example, the temperature dependence of the lattice heat capacity can be well accounted for within the harmonic approximation of the lattice vibrations by the Debye model [1]. In particular, the Debye model, in accordance with experiment, predicts that at high temperatures T [ T D (T D ¼ hx D =k B is the Debye temperature, x D is the Debye frequency -the highest allowed phonon frequency in the crystal, ℏ is the Planck constant divided by 2π, and k B is the Boltzmann constant), the lattice heat capacity can be approximated by the classical value C % 3Nk B =V (N is the number of atoms in the crystal volume V), which is known as Dulong and Petit value; whilst at low temperatures T \T D the lattice heat capacity starts to decrease (following C ∼ T 3 law at T ( T D ) which is a reflection of quantum effects on the phonon population [1].

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Phonon-mediated heat dissipation in a monatomic lattice: case study on Ni

Levchenko

Evteev

Momenzadeh

et al. 2015

Philosophical Magazine

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The thermal conductivity decomposition of calcite calculated by molecular dynamics simulation

Momenzadeh

Moghtaderi

Buzzi

et al. 2018

Computational Materials Science

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