Temperature-Gradient Effects on Electric Double Layer Screening in Electrolytes

Abstract

Temperature gradients drive asymmetric ion distributions via thermodiffusion (the Soret effect), leading to deviations from the classical Debye--H\"uckel potential.We introduce the Eastman entropy of transfer, S = α k B for cations and anions, respectively, where k B is the Boltzmann constant, and analyze non-isothermal electric double layers in terms of the dimensionless Soret coefficients α. Analytical solutions of the generalized Debye--H\"uckel equation show that, for α+ = α-, the potential is exactly described by a modified Bessel function, while the marginal case α = 1 exhibits algebraic decay. An effective screening length, λ eff, characterizes the near-electrode potential and increases with temperature, resulting in weaker screening on the hot side and stronger screening on the cold side for α > -1. The differential capacitance is controlled by α via λ eff, with its minimum coinciding with the potential of zero charge (PZC) even in the presence of a temperature gradient. These findings highlight the fundamental coupling between electrostatics and thermodiffusion in non-isothermal electrolytes.

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