is electron temperature or ion temperature in plasma.
Stokes–Einstein equation
In the limit of low Reynolds number, the mobility μ is the inverse of the drag coefficient. A damping constant is frequently used for the inverse momentum relaxation time of the diffusive object. For spherical particles of radius r, Stokes' law gives where is the viscosity of the medium. Thus the Einstein–Smoluchowski relation results into the Stokes–Einstein relation This has been applied for many years to estimating the self-diffusion coefficient in liquids, and a version consistent with isomorph theory has been confirmed by computer simulations of the Lennard-Jones system. In the case of rotational diffusion, the friction is, and the rotational diffusion constant is
By replacing the diffusivities in the expressions of electric ionic mobilities of the cations and anions from the expressions of the equivalent conductivity of an electrolyte the Nernst–Einstein equation is derived:
Proof of the general case
The proof of the Einstein relation can be found in many references, for example see Kubo. Suppose some fixed, external potential energy generates a conservative force on a particle located at a given position. We assume that the particle would respond by moving with velocity. Now assume that there are a large number of such particles, with local concentration as a function of the position. After some time, equilibrium will be established: particles will pile up around the areas with lowest potential energy, but still will be spread out to some extent because of diffusion. At equilibrium, there is no net flow of particles: the tendency of particles to get pulled towards lower, called the drift current, perfectly balances the tendency of particles to spread out due to diffusion, called the diffusion current. The net flux of particles due to the drift current is i.e., the number of particles flowing past a given position equals the particle concentration times the average velocity. The flow of particles due to the diffusion current is, by Fick's law, where the minus sign means that particles flow from higher to lower concentration. Now consider the equilibrium condition. First, there is no net flow, i.e.. Second, for non-interacting point particles, the equilibrium density is solely a function of the local potential energy, i.e. if two locations have the same then they will also have the same That means, applying the chain rule, Therefore, at equilibrium: As this expression holds at every position, it implies the general form of the Einstein relation: The relation between and for classical particles can be modeled through Maxwell-Boltzmann statistics where is a constant related to the total number of particles. Therefore Under this assumption, plugging this equation into the general Einstein relation gives: which corresponds to the classical Einstein relation.
