Transport coefficient

A transport coefficient $\gamma$ measures how rapidly a perturbed system returns to equilibrium.

The transport coefficients occur in transport laws ${\mathbf {J} {_{k}}}\,=\,\gamma _{k}\,\mathbf {X} {_{k}}$ where:

{\mathbf {J} {_{k}}}

is a flux of the property

k

the transport coefficient

\gamma _{k}

of this property

k

{\mathbf {X} {_{k}}}

, the gradient force which acts on the property

k

.

Transport coefficients can be expressed via a Green–Kubo relation:

\gamma =\int _{0}^{\infty }\langle {\dot {A}}(t){\dot {A}}(0)\rangle \,dt,

where $A$ is an observable occurring in a perturbed Hamiltonian, $\langle \cdot \rangle$ is an ensemble average and the dot above the A denotes the time derivative.[1] For times $t$ that are greater than the correlation time of the fluctuations of the observable the transport coefficient obeys a generalized Einstein relation:

2t\gamma =\langle |A(t)-A(0)|^{2}\rangle .

In general a transport coefficient is a tensor.

Examples

Diffusion constant, relates the flux of particles with the negative gradient of the concentration (see Fick's laws of diffusion)
Thermal conductivity (see Fourier's law)
Mass transport coefficient
Shear viscosity $\eta ={\frac {1}{k_{B}TV}}\int _{0}^{\infty }dt\,\langle \sigma _{xy}(0)\sigma _{xy}(t)\rangle$ , where $\sigma$ is the viscous stress tensor (see Newtonian fluid)
Electrical conductivity

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References

Water in Biology, Chemistry, and Physics: Experimental Overviews and Computational Methodologies, G. Wilse Robinson, ISBN 9789810224516, p. 80, Google Books

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[1] Water in Biology, Chemistry, and Physics: Experimental Overviews and Computational Methodologies, G. Wilse Robinson, ISBN 9789810224516, p. 80, Google Books

Transport coefficient

Examples

See also

References