Optimizing fog harvesting by biomimicry

TL;DR

This study optimizes fog harvesting surfaces inspired by beetle morphology by analyzing the effects of patch size and inclination on water storage capacity, validated through experiments and dynamic modeling for improved water collection.

Contribution

It presents a theoretical and experimental framework for maximizing water storage on biomimetic surfaces with hydrophilic patches, advancing fog harvesting technology.

Findings

Optimal patch radius prevents dewetting and overflow.

Maximum storage conditions align with maximum fog collection efficiency.

Experimental validation confirms theoretical predictions.

Abstract

Inspired by the stenocara beetle, we study an ideal flat surface composed of a regular array of hydrophilic circular patches in a hydrophobic matrix on an incline of tilt $\alpha$ with respect to the horizontal. Based on an exact solution of the Laplace-Young equation at first order in the Bond number, the liquid storage capacity of the surface is maximized as function of the patch radius, for suitable ranges of hydrophilic and hydrophobic contact angles, for tilt angles such as $45^{\circ}$ or $90^\circ$. It is found that the optimal radius equally prevents dewetting from the top of the patches and overflow at the bottom. These theoretical considerations are validated by several experiments for the glass/octadecyltrichlorosilane (OTS) system involving different patch sizes and different inclinations. In a simple dynamical model, taking into account the flux of fog onto the surface or condensation on a suitably cooled surface, we find that the conditions for maximum harvest agree with the ones of maximum static storage. The method could be developed for drop storage and drop transport applications such as water-harvesting systems.