Hydrogen produced by using solar energy could contribute to a climate neutral energy system of the future. But there are hurdles on the way from laboratory scale to large-scale implementation.
A team at HZB has now presented a method to visualize convection in the electrolyte and to reliably simulate it in advance with a multiphysics model. The results can support the design and scaling up of this technology and have been published in the renowned journal Energy and Environmental Science.
The local pH value changes over time (here in an electrolyte with 0.5 MK 2 SO 4 ). © HZB
Hydrogen can be produced with renewable energies in a climate neutral way and could make a major contribution to the energy system of the future. One of the options is to use sunlight for electrolytic water splitting, either indirectly by coupling a solar cell with an electrolyser or directly in a photoelectrochemical (PEC) cell. Light-absorbing semiconductors serve as photoelectrodes. They are immersed in an electrolyte solution of water mixed with strong acids or bases, which contains high concentration of protons or hydroxide ions necessary for efficient electrolysis.
Efficiency versus security
However, in a large-scale plant, it would make sense for safety reasons to use an electrolyte solution with a near-neutral pH. Such a solution has a low concentration of protons and hydroxide ions, which leads to mass-transport limitations and poor performance. Understanding these limitations is essential to design a safe and scalable PEC water splitting device.
Currents during electrolysis
A team led by Dr. Fatwa Abdi from the HZB Institute for Solar Fuels has now for the first time investigated how the liquid electrolyte throughout the cell behaves during electrolysis: With the help of fluorescent pH-sensor foils, Dr. Keisuke Obata, a postdoc in Abdi’s team, determined the local pH value in PEC cells between the anode and cathode during the course of electrolysis. The PEC cells were filled with near-neutral pH electrolytes.
The scientists experimentally visualized the decrease of pH at regions close to the anode and the increase of pH at regions close to the cathode. Interestingly, they observed a clock-wise motion of the electrolyte as the electrolysis proceeds. The observation can be explained by buoyancy due to changes of electrolyte density during the electrochemical reaction which leads to convection. “It was surprising to see that tiny changes in electrolyte density (~0.1%) cause this buoyancy effect,” says Abdi.
Model enables simulation
In parallel, Abdi and his team developed a multiphysics model to calculate the convection induced by electrochemical reactions. “We have thoroughly tested this model and can provide now a powerful tool to simulate natural convection in an electrochemical cell with various electrolytes in advance,” says Abdi.
For the project Abdi has built up a “Solar Fuel Devices Facility” at HZB, which is part of the Helmholtz Energy Materials Foundry (HEMF), a big infrastructure open to other scientists as well. This study was also performed in collaboration with TU Berlin, within the framework of UniSysCat cluster of excellence.
“With this work we are expanding our materials science expertise with efforts on photoelectrochemical reactor engineering, which is an essential next step for the scale-up of solar fuel devices” says Prof. Dr. Roel van de Krol, who heads the HZB Institute for Solar Fuels.
Keisuke Obata, Roel van de Krol, Michael Schwarze, Reinhard Schomäcker, and Fatwa F. Abdi
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