Takie coś znalazłem:
At the large production volumes necessary for gigawatt-scale grid storage, it is possible that DBEAQ may approach the cost of other functionalized anthraquinones, such as DHAQ and AQDS, the latter of which was recently estimated to be between $0.92/kg and $3.92/kg.23 Using $2.40/kg as a mid-range cost, this results in a capital cost of $17.60/kWh for the 2-electron-accepting DBEAQ in the negolyte in a 1.05 V battery. Similarly, we estimate the industrial-scale cost of potassium ferrocyanide to be around $2.15/kg,24 which amounts to a capital cost of about $32/kWh for the posolyte (see Estimated Cost of Electrolytes in the Supplemental Information). At $50/kWh, the total capital cost of these electrolytes stands at less than one-third of the cost of an all-vanadium electrolyte, for which the vanadium alone is currently priced at $160/kWh. Using a fluorine-free membrane such as Fumasep E−620 (K) should result in a product of membrane cost (<$25/m2 at large production volumes) and ASR (<1.5 Ω cm2) that is below $5/mΩ, which adds negligible cost to the system.25 Thus, if the DBEAQ production cost at scale turns out to be nearly as low as for AQDS and DHAQ,23,26 then this chemistry may have serious commercial potential, and DBEAQ-based flow batteries may be instrumental in accelerating the penetration of wind and photovoltaic electricity.