Exploring electrolysis for energy storage

  • Many renewables, though, can be frustratingly intermittent when the sun stops shining, or the wind stops blowing, the power flickers.
  • The fluctuating supply can be partly smoothed-out by energy storage during peak production times. However, storing electricity is not without its challenges either.
  • Glycolic acid (GC) has a much greater energy capacity than hydrogen, one of the more popular energy-storage chemicals.
  • GC can be produced by four-electron reduction of oxalic acid (OX), a widely available carboxylic acid.
  • Researchers devised an electrolytic cell based on a novel membrane-electrode assembly.
  • Sandwiched between two electrodes are an iridium oxide-based anode and a titanium dioxide (TiO2)-coated titanium (Ti) cathode, linked by a polymer membrane.
  • Flow-type systems are very important for energy storage with liquid-phase reaction.
  • In this device , by using solid polymer electrolyte in direct contact with the electrodes, we can run the reaction as a continuous flow without addition of impurities (e.g. electrolytes).
  • The OX solution can effectively be thought of as a flowable electron pool. The cathodic reaction is catalyzed by anatase TiO2. To ensure a solid connection between catalyst and cathode, the team “grew” TiO2directly on Ti in the form of a mesh or felt.
  • Electron microscope images show the TiO2as a wispy fuzz, clinging to the outside of the Ti rods like a coating of fresh snow. In fact, its job is to catalyze the electro-reduction of OX to GC. Meanwhile, at the anode, water is oxidized to oxygen.
  • The reaction accelerated at higher temperatures. However, turning the heat up too high encouraged an unwanted by-process the conversion of water to hydrogen.
  • The ideal balance between these two effects was at 60°C. At this temperature, the device could be further optimized by slowing the flow of reactants, while increasing the amount of surface area available for the reaction.
  • Interestingly, even the texture of the fuzzy TiO2catalyst made a major difference.
  • When TiO2was prepared as a “felt,” by growing it on thinner and more densely packed Ti rods, the reaction occurred faster than on the “mesh” probably because of the greater surface area.
  • The maximum volumetric energy capacity of the GC solution is around 50 times that of hydrogen gas. To be clear, the energy efficiency, as opposed to capacity, still lags behind other technologies. However, this is a promising first step to a new method for storing excess current.


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