Aqueous battery


An aqueous battery is an electric battery that uses a water-based solution as an electrolyte. Aqueous batteries have existed since the 1860s. While most designs do not have the energy density and cycle life required by typical use cases, they are generally considered safer, more reliable and relatively inexpensive in comparison to lithium-ion batteries. Until the 2010s, aqueous batteries also found a niche in high-power applications like cordless power tools, but developments in Li-ion chemistry enabled Li-ion batteries to replace them.

Commercial history

The lead–acid battery was invented by Gaston Planté in 1859, although the commercialization of the diluted sulphuric acid electrolyte design took twenty years of work by multiple inventors. After an additional half a century the modern valve-regulated batteries appeared in 1930s.
Alkaline batteries first appeared at the turn of the 20th century with nickel–cadmium battery replaced by nickel–metal hydride one in the 1980s.
In the early 2020s the aqueous batteries comprised half of the market for rechargeable batteries.

Advantages

When compared to the lithium-ion batteries, the aqueous ones have the following advantages:
  • safety and reliability is related to non-flammability, high tolerance against mechanical mishandling, and resistance to overcharging ;
  • low cost is based on cheap raw materials, manufacturing that does not require oxygen-free environments, minimum of electronics due to inherent safety and reliability;
  • fast reaction rate allows faster charging and discharging and provides consistency over the temperature range.

    Disadvantages

In comparison to the lithium-ion batteries have the following drawbacks:
  • a narrow electrochemical window: water starts electrolysing at the potential of 1.23 volts. Although a clever choice of materials can stretch the window to 2.3 V and utilizing a high-concentration electrolyte can widen the window to 3 V, in practice only the lead-acid batteries reach 2 V, with the rest of the designs in production limited to the potential slightly above 1 V, thus greatly limiting the energy density. Both volumetric and mass energy densities of the lithium-ion batteries are 2-3 times better;
  • water being an aggressive solvent causes solvation and dissociation of battery components and can cause corrosion, limiting the choice of materials and lifetime of the battery;
  • cycle life is an order of magnitude lower.

    Research

The aqueous batteries are subject to an extensive research in the 21st century ; the material innovations since the beginning of the century allow better performance that that of the "traditional" aqueous batteries might lead to these batteries evolving into a companion to the lithium-ion ones in the fields of transportation and electricity storage.
Tahir et al. identify the following directions of research: