Isaac Holmes-Gentle scite author profile

Many photoelectrodes produce a gaseous product, such as hydrogen or oxygen, from a liquid electrolyte and require light transmission directly through the two-phase mixture forming at the semiconductor–electrolyte interface. Consequently, incidence solar photons will be scattered and reflected from the bubbly mixture leading to an additional optical loss. In this work, these optical losses are quantified for a population of bubbles that evolved from the vertical surface of a transparent conductive electrode (F-SnO2) by measuring the amount of light transmitted. The transmitted photons were collected in an integrating sphere placed directly behind the 15 mm × 15 mm electrode to capture the forward scattered light. The empirical results were compared with a simple dimensionless model. Finally, mitigation strategies are suggested and critically discussed. With progress in the development of large scale prototype photoelectrochemical devices comes the need to understand, quantify, and potentially resolve the issue of optical losses from gas evolving photoelectrodes.

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Membrane-less photoelectrochemical cells: product separation by hydrodynamic control

Holmes-Gentle

Hoffmann

Mesa

et al. 2017

Sustainable Energy Fuels

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A key step in order to realise photo-electrochemical (PEC) water splitting to produce hydrogen sustainably, is reactor design. Good engineering will minimise energy losses (both optical and ohmic) due to reactor construction, whilst ensuring the H 2 and O 2 produced are separated, and this can subsequently relax the requirements on the photo-absorber material and/or electrocatalysts. In this paper we show that separation of the products through hydrodynamic flow alone would negate the need for the conventionally used membrane, which has an associated ohmic drop and cost. This is demonstrated to be possible using a 'laminar flow between two parallel plates' reactor design and AR/Pe and AR are found to be the two key dimensionless numbers that predict product cross-over (where AR, Pe are Aspect Ratio and Péclet number respectively). Supersaturation was used as an indicator of bubble formation, which disrupts the laminar flow required for separation and it is shown that by increasing the reactor pressure, higher current densities can be tolerated before supersaturation occurs. Removal of the dissolved hydrogen and oxygen from electrolyte is discussed. A multi-physics model, which employs an optical transfer matrix method, is used to validate the previous conclusions. Experimental data for hematite and Pt deposited on FTO was used as the anode and cathode respectively. Parasitic optical losses and efficiency improvement with stacking are shown for the example reactor configuration. Additionally, the concept of stacking this reactor design in order to absorb light in multiple passes is introduced. This approach relaxes a classical constraint on photo-absorber materials: Large absorption length compared to small diffusion length of charge carriers in the semiconductor.

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Effects of low temperature annealing on the photo-electrochemical performance of tin-doped hematite photo-anodes

Bedoya-Lora

Hankin

Holmes-Gentle

et al. 2017

Electrochimica Acta

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Dynamic system modeling of thermally-integrated concentrated PV-electrolysis

Holmes-Gentle

Tembhurne

Suter

et al. 2021

International Journal of Hydrogen Energy

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Electrochemical techniques for photoelectrode characterisation

Bedoya-Lora

Holmes-Gentle

Hankin

2021

Current Opinion in Green and Sustainable Chemistry

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