English

On the time-dependent electrolyte Seebeck effect

Chemical Physics 2021-05-03 v2 Soft Condensed Matter

Abstract

Single-ion Soret coefficients αi\alpha_{i} characterize the tendency of ions in an electrolyte solution to move in a thermal gradient. When these coefficients differ between cations and anions, an electric field can be generated. For this so-called electrolyte Seebeck effect to occur, the different thermodiffusive fluxes need to be blocked by boundaries -- electrodes, for example. Local charge neutrality is then broken in the Debye-length vicinity of the electrodes. Confusingly, many authors point to these regions as the source of the thermoelectric field yet ignore them in derivations of the time-dependent Seebeck coefficient S(t)S(t), giving a false impression that the electrolyte Seebeck effect is purely a bulk phenomenon. Without enforcing local electroneutrality, we derive S(t)S(t) generated by a binary electrolyte with arbitrary ionic valencies subject to a time-dependent thermal gradient. Next, we experimentally measure S(t)S(t) for five acids, bases, and salts near titanium electrodes. For the steady state we find S2 mV K1S\approx2~\mathrm{mV~K}^{-1} for many electrolytes, roughly one order of magnitude larger than predictions based on literature αi\alpha_{i}. We fit our expression for S(t)S(t) to the experimental data, treating the αi\alpha_{i} as fit parameters, and also find larger-than-literature values, accordingly.

Keywords

Cite

@article{arxiv.2006.11081,
  title  = {On the time-dependent electrolyte Seebeck effect},
  author = {André Luiz Sehnem and Mathijs Janssen},
  journal= {arXiv preprint arXiv:2006.11081},
  year   = {2021}
}

Comments

9 pages, 4 figures + supplementary material (8 pages, 5 figures)

R2 v1 2026-06-23T16:27:43.618Z