# Gas bubble evolution on microstructured silicon substrates

**Authors:** Peter van der Linde, Pablo Pe\~nas-L\'opez, \'Alvaro Moreno Soto,, Devaraj van der Meer, Detlef Lohse, Han Gardeniers, David Fern\'andez Rivas

arXiv: 1901.07326 · 2019-01-23

## TL;DR

This study investigates gas bubble formation, growth, and detachment on microstructured silicon electrodes, revealing distinct regimes influenced by gas depletion and supersaturation, with implications for electrolysis efficiency.

## Contribution

It provides new insights into the dynamics of hydrogen and carbon dioxide bubbles on microstructured surfaces, highlighting different growth regimes and size distributions during electrolysis.

## Key findings

- Bubble growth rates decrease due to gas depletion in CO2 cases.
- Electrolytic H2 bubbles exhibit three growth regimes influenced by boundary layer evolution.
- Detachment sizes are smaller than theoretical predictions and vary widely.

## Abstract

The formation, growth and detachment of gas bubbles on electrodes are omnipresent in electrolysis and other gas-producing chemical processes. To better understand their role in the mass transfer efficiency, we perform experiments involving successive bubble nucleations from a predefined nucleation site which consists of a superhydrophobic pit on top of a micromachined pillar. The experiments on bubble nucleation at these spots permit the comparison of mass transfer phenomena connected to electrolytically generated H$_2$ bubbles with the better-understood evolution of CO$_2$ bubbles in pressure-controlled supersaturated solutions. In both cases, bubbles grow in a diffusion-dominated regime. For CO$_2$ bubbles, it is found that the growth rate coefficient of subsequent bubbles always decreases due to the effect of gas depletion. In contrast, during constant current electrolysis, the bubble growth rates are affected by the evolution of a boundary layer of dissolved H$_2$ gas near the flat electrode which competes with gas depletion. This competition results in three distinct regimes. Initially, the bubble growth slows down with each new bubble in the succession due to the dominant depletion of the newly-formed concentration boundary layer. In later stages, the growth rate increases due to a local increase of gas supersaturation caused by the continuous gas production and finally levels off to an approximate steady growth rate. The gas transport efficiency associated with the electrolytic bubble succession follows a similar trend in time. Finally, for both H$_2$ and CO$_2$ bubbles, detachment mostly occurs at smaller radii than theory predicts and at a surprisingly wide spread of sizes. A number of explanations are proposed, but the ultimate origin of the spreading of the results remains elusive.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1901.07326/full.md

## References

50 references — full list in the complete paper: https://tomesphere.com/paper/1901.07326/full.md

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Source: https://tomesphere.com/paper/1901.07326