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Salinity-dependent interfacial phenomena toward hydrovoltaic device optimization

Tarique Anwar, Giulia Tagliabue

2024Device14 citationsDOIOpen Access PDF

Abstract

Hydrovoltaic (HV) devices are an emerging technology for sustainable energy generation. By leveraging ordered arrays of silicon nanopillars (NPs) and developing a quantitative multiphysics model, this work reveals the complex interplay of surface charge, liquid properties, and geometrical parameters in these systems, including previously unexplored electrokinetic interactions. Notably, we find that ion-concentration-dependent surface charge, together with ion mobility, dictates multiple local maxima in open-circuit voltage, with optimal conditions deviating from conventional low-concentration expectations. Beyond electrokinetic parameters, we show that structural asymmetries generate an electrostatic potential, augmenting HV performance. Finally, for molar-level concentrations, we provide evidence of ion adsorption and charge inversion for several monovalent cations, enabling HV devices to operate even at such high concentrations. Overall, we can uniquely demonstrate a high power density output of 8 μW/cm2 at 0.1 M. Our work thus paves the way for the broader applicability of HV systems across salinity scales.

Topics & Concepts

SalinityEnvironmental scienceGeologyOceanographySolar-Powered Water Purification MethodsSolar Thermal and Photovoltaic SystemsThermal Radiation and Cooling Technologies
Salinity-dependent interfacial phenomena toward hydrovoltaic device optimization | Litcius