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New electrolyzer to split saltwater into hydrogen – pv magazine International

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Chinese language scientists have developed a brand new solution to break up seawater into hydrogen with out utilizing a separate desalination course of. They hooked up a self-breathable waterproof membrane and a self-dampening electrolyte (SDE) to the electrolyzer, so water migrates from seawater throughout the membrane to the SDE, with out extra power consumption.

Researchers from Shenzhen College and Nanjing Tech College in China have developed a seawater electrolysis system (SES) for the direct electrolysis of seawater, with out aspect reactions or corrosion.

The brand new methodology works by way of self-driven water migration to keep away from the necessity for a separate desalination course of. The power consumption is alleged to be corresponding to industrial alkaline electrolysis with pure water.

To develop the lab-scale electrolyzer, scientists separated the 2 electrode layers with a diaphragm layer after which immersed them in a concentrated hydroxide (OH−) answer – the SDE. They positioned a polytetrafluoroethylene (PTFE) membrane between the seawater and the SDE. They declare that this design permits the partial diffusion of water vapor, however fully prevents the entry of liquid sea water and impurity ions corresponding to magnesium, chloride and sulfate.

“Throughout operation, the distinction in water vapor strain between the seawater and the SDE throughout the membrane supplies a driving pressure for the speedy gasification of the seawater (evaporation) on the water aspect of the ocean ​​and the diffusion of water vapor by way of a brief fuel passage contained in the membrane to the aspect of the SDE, the place it’s re-liquefied by the absorption of the SDE,” defined the scientist.

The consumption of water within the SDE throughout electrolysis maintains the strain distinction throughout the membrane, guaranteeing steady entry of recent water, with out extra power consumption.

“When the speed of water migration equals the speed of electrolysis, a brand new thermodynamic equilibrium is established between seawater and the SDE, and the continual and steady migration of water by way of the mechanism ‘liquid- gas-liquid’ is realized to supply recent water for electrolysis,” the researchers stated.

The lab-scale electrolyzer repeatedly produced hydrogen from seawater for over 72 hours, with a median voltage of roughly 1.95 V and a couple of.3 V at a present density of 250 mA cm-2 and 400 mA cm-2, respectively. After 72 hours, the focus of chloride, sulfate, and magnesium impurities was solely 0.008%, 0.052%, and 0.089% of the unique.

“Calculations present that the price of electrical energy in [hydrogen] manufacturing is roughly 4.6 kWh Nm-3H2 and 5.3 kWh Nm-3H2 at a present density of 250 mA cm-2 and 400 mA cm-2.

To show the idea, they created a scaled-up SES measuring 82 cm x 62 cm x 70.5 cm. It’s reported to indicate steady efficiency for greater than 3,200 hours and power consumption of roughly 5.0 kWh Nm-3H2with no noticeable improve in impurity ions.

The scientists stated that their methodology might be additional improved by utilizing different electrolytes that may take in water vapor and conduct ions, or high-performance electrocatalysts that may work round SDE. They added that the technique might be utilized to different non-volatile liquids corresponding to extremely concentrated acid, alkali and salt options to be used in industrial wastewater therapy.

As well as, it may be used to supply hydrogen whereas recovering helpful sources corresponding to lithium from water. Additional analysis can be wanted for the compatibility of the electrolyzer with sources of renewable power which are appropriate with standard electrolyzers.

The scientists shared their findings in “A membrane-based seawater electrolyser for hydrogen technology,” which was lately revealed in NATURE.

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