Add to ORKGWe present a microscopic derivation of the nonlinear fluctuating hydrodynamic equation for the homogeneous crystalline solid from the Hamiltonian description of a many-particle system. We propose a microscopic expression of the displacement field that correctly generates the nonlinear elastic properties of the solid and find the nonlinear mode-coupling terms in reversible currents which are consistent with the phenomenological equation. The derivation relies on the projection onto the coarse-grained fields including the displacement field, the long-wavelength expansion, and the stationarity condition of the Fokker-Planck equation.Comment: 11 page
The derivation of time evolution equations for slow collective variables starting from a micro- scop...
Kinetic and hydrodynamic theories are widely employed for describing the collective behaviour of act...
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Starting from a general classical model of many interacting particles we present a well defined step...
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© 2016 American Physical Society. The phase-field-crystal (PFC) approach extends the notion of phase...
We study a periodic medium driven over a random or periodic substrate, characterizing the nonequilib...
We study steady-state dynamic fluctuations of current and mass, as well as the corresponding power s...
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The local equilibrium approach previously developed by the authors (J Mabillard and P Gaspard 2020 J...
A dynamical atomistic chain to simulate mechanical properties of a one-dimensional material with zer...
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We consider a quantum Langevin kinetic equation for a system of fermions. We first derive the Langev...
The derivation of time evolution equations for slow collective variables starting from a micro- scop...
Kinetic and hydrodynamic theories are widely employed for describing the collective behaviour of act...
We introduce a model described in terms of a scalar velocity field on a 1D lattice, evolving through...
Starting from a general classical model of many interacting particles we present a well defined step...
We present an isothermal fluctuating nonlinear hydrodynamic theory of crystallization in molecular l...
We present a microscopic derivation of the laws of continuum mechanics of nonideal ordered solids in...
We study charged hydrodynamics in a periodic lattice background. Fluctuations are Bloch waves rather...
© 2016 American Physical Society. The phase-field-crystal (PFC) approach extends the notion of phase...
We study a periodic medium driven over a random or periodic substrate, characterizing the nonequilib...
We study steady-state dynamic fluctuations of current and mass, as well as the corresponding power s...
Formally, we consider the continuum field of conserved quantities U(r, t) = ρj e ∼ = Ũ(r, t) =...
The local equilibrium approach previously developed by the authors (J Mabillard and P Gaspard 2020 J...
A dynamical atomistic chain to simulate mechanical properties of a one-dimensional material with zer...
We construct a new hydrodynamic framework describing plastic deformations in electronic crystals. Th...
We consider a quantum Langevin kinetic equation for a system of fermions. We first derive the Langev...
The derivation of time evolution equations for slow collective variables starting from a micro- scop...
Kinetic and hydrodynamic theories are widely employed for describing the collective behaviour of act...
We introduce a model described in terms of a scalar velocity field on a 1D lattice, evolving through...