(287b) Effect of Br2 Complexation on a Hydrogen-Bromine Flow Battery Performance

Hydrogen-bromine flow batteries offer a viable solution for storing energy from the electrical grid or directly from renewable energy sources such as wind and solar due to its high roundtrip efficiency and relatively low cost. During charge, a hydrogen-bromine flow battery stores energy in the form of hydrogen (H₂) and bromine (Br₂). During discharge, hydrobromic acid (HBr) is produced. One of the major issues with the hydrogen-bromine flow battery system is the difficulty of safely storing bromine. Bromine has a high vapor pressure, is toxic and very corrosive. Past research has shown that complexing Br₂ with organic molecules is an effective way to reduce the amount of free bromine in the solution, thus reducing its vapor pressure and corrosivity. For example, Eustace demonstrated how quarternary ammonium salts could be complexed with bromine in zinc-bromine flow batteries.¹ Kosek et al previously studied the complexation of bromine using polyethylene glycol (PEG).² Kosek et al performed kinetic studies of PEG-1000 in concentration ranges of 1-5M and temperatures of 24-43^oC, observing the highest dissociation rates occurred at 3M HBr and room temperature.²

In this study, we will use different types of complexing agents at various concentrations to determine the most suitable conditions for reducing the concentration of free bromine while also maintaining high bromine electroactivity. Electrochemical measurement techniques using a rotating disc electrode will be used to acquire the kinetic reaction parameters of interest, including the exchange current density and charge transfer coefficients. The effect of using complexing agents in the HBr/Br₂ electrolyte will then be tested in an actual fuel cell to obtain polarization curves. This information is expected to determine the viability of using a complexing agent in an actual hydrogen-bromine fuel cell system in order to reduce the concentration of free Br₂ while also enabling high performance.

References:

1. D.J. Eustace, J. Electrochem. Soc., 127, 3 (1980).
2. J.A. Kosek and A.B. LaConti, Investigation of Bromine Complexed Hydrogen/Bromine Regenerative Fuel Cells for Portable Electric Power, General Electric Final Report to U.S. Army Mobility Equipment Research and Development Command, Sept 1984.