Battery recycling

Battery recycling is a recycling activity that aims to reduce the number of batteries being disposed as municipal solid waste. Batteries contain a number of heavy metals and toxic chemicals and disposing of them by the same process as regular household waste has raised concerns over soil contamination and water pollution. While reducing the amount of pollutants being released through disposal through the uses of landfill and incineration, battery recycling can facilitate the release of harmful materials from batteries to both the environment and the workers recycling batteries.

Battery recycling by type

Most types of batteries can be recycled. However, some batteries are recycled more readily than others, such as lead–acid automotive batteries and button cells. Rechargeable nickel–cadmium, nickel–metal hydride battery, lithium-ion and nickel–zinc, can also be recycled. Disposable alkaline batteries make up the vast majority of consumer battery use, but there is currently no cost-neutral recycling option. Consumer disposal guidelines vary by region. An evaluation of consumer alkaline battery recycling in Europe showed environmental benefit but at significant expense over disposal. Zinc–carbon and Zinc–air batteries are recycled in the same process. E.U. consumers recycled almost half of portable batteries bought in 2017.

Lead–acid batteries

Lead-acid batteries include but are not limited to: car batteries, golf cart batteries, UPS batteries, industrial fork-lift batteries, motorcycle batteries, and commercial batteries. These can be regular lead–acid, sealed lead–acid, gel type, or absorbent glass mat batteries. These are recycled by grinding them, neutralizing the acid, and separating the polymers from the lead. The recovered materials are used in a variety of applications, including new batteries.
The lead in a lead–acid battery can be recycled. Elemental lead is toxic and should therefore be kept out of the waste stream.
The casing of a lead–acid battery is often made of either polypropylene or ABS, which can also be recycled, although there are significant limitations on recycling plastics.
Many cities offer battery recycling services for lead–acid batteries. In some jurisdictions, including U.S. states and Canadian provinces, a refundable deposit is paid on batteries. This encourages recycling of old batteries instead of abandonment or disposal with household waste. Businesses that sell new car batteries may also collect used batteries for recycling.
A 2019 study commissioned by battery-industry promotional group, the Battery Council, calculated battery lead recycling rates in the United States in the period 2014–2018, taking into account battery scrap lead import/export data from the Department of Commerce. The report says that, after accounting for net scrap battery lead exports from the United States, 99.0% of the remaining lead from lead-acid batteries in the United States is reclaimed. The Battery Council figures indicate that around 15.5 billion pounds of battery lead was consumed in the USA in that period, with a net amount of approximately 2 billion pounds battery scrap lead being exported. Of the 13.6 billion pounds remaining after exports, 13.5 billion pounds were recycled.
The U.S. Environmental Protection Agency, has reported lesser and varying levels of lead-acid battery recycling in the United States in earlier years, under various administrations, Republican and Democrat. The EPA reported in 1987 that varying economics and regulatory requirements have contributed to rates of 97 percent in 1965, above 83 percent in 1980, 61 percent in 1983, and around 70 percent in 1985.
According to a 1992 EPA Superfund report, lead batteries account for about 80% of the lead used in the United States, of which about 60% is reclaimed during times of low lead prices, but more in times of high lead prices; it reported that 50% of the nation's lead needs are filled from recycled lead.

Silver-oxide batteries

Used most frequently in watches, toys, and some medical devices, silver-oxide batteries contain a small amount of mercury. Most jurisdictions regulate their handling and disposal to reduce the discharge of mercury into the environment. Silver oxide batteries can be recycled to recover the mercury through the use of both Hydrometallurgical methods and pyrometallurgical methods.
More recent silver oxide batteries no longer contain mercury and the process of recycling them does not give cause for concern for releasing mercury into the environment.

Lithium-ion batteries

Estimates for recycling rates for lithium batteries vary greatly. The U.S. Government and others estimating in 2021 that at most 15% were recycled at end of life in 2019. However, some recycling advocates claim that most lithium-ion batteries were recycled. They contain lithium and high-grade copper and aluminium. Depending on the active material, they may also contain cobalt and nickel. Many products use lithium-ion batteries from electronics and handheld power tools to electric vehicles and electrical energy storage systems. To prevent a future shortage of cobalt, nickel, and lithium and to enable a sustainable life cycle of these technologies, recycling processes for lithium batteries are needed. These processes have to regain not only cobalt, nickel, copper, and aluminium from spent battery cells, but also a significant share of lithium. Other potentially valuable and recoverable materials are graphite and manganese. Recycling processes today recover approximately 25% to 96% of the materials of a lithium-ion battery cell. In order to achieve this goal, several steps are combined into complex process chains, while ensuring safety.
These steps are:

Deactivation or discharging of the battery
Disassembly of battery systems
Mechanical processes
Electrolyte recovery
Metal recovery processes
Hydrometallurgical method

One or more of these metal recovery processes are used to recover critical metals from battery waste. In hydrometallurgical methods, metals are first extracted in aqueous solution, typically using acids and hydrogen peroxide as a reducing agent. This is followed by selective precipitation of the metals as salts. Hydrometallurgical processes have several advantages, such as low energy consumption, low cost and little hazardous gas emission. However, the use of dangerous acids during extraction poses safety concerns. Additionally, the method requires extensive and complicated processing to selectively precipitate each metal salt.

Pyrometallurgical method

Similar to hydrometallurgical methods, the primary aim of most pyrometallurgical recycling processes is the recovery of valuable minerals from the cathode electrode. Thus, the first step is frequently the separation of the cathode material from the rest of the cell components. In typical pyrometallurgical processes, this separation step can be divided into two categories: incineration and pyrolysis. While incineration generally requires lower temperatures and shorter times than pyrolysis, pyrolysis offers the advantage of lower CO/CO₂ emissions and the potential to recover some organic compounds by capturing and processing the off-gases. After decomposing the organic components of the cell, the remaining cathode material can either be separated from the Al current collector for roasting or the cathode and current collector can be used together for smelting. Smelting can also be performed without pretreatment using the entire battery cell, but this requires additional low temperature steps to prevent explosions from rapid electrolyte evaporation.
For smelting processes, high temperatures are used to melt the Al-cathode mixture, which then reacts with the slag mixture to form a transition metal rich alloy phase below the slag. This alloy phase can then be refined using traditional leaching methods to separate and purify the metallic species. While the conventional smelting process cannot recover Li or Mn from cathode materials, changes in the slag system have been proposed to allow for recovery of these metals as well.
In roasting processes, the cathode material is heated in the presence of either a carbon source or a salt compound to yield extractable forms of the desired metals. In the carbothermal reduction process, the result is a mixed-metal alloy similar that of the smelting process but using a lower temperature of 650-1000 °C. In the salt-assisted process, the reaction of the cathode material with the salts produces water-soluble metal products that can be easily recovered. This can also be done at temperatures as low as 200 °C in some systems. Both roasting approaches also have the benefit of being able to recover Li from the spent batteries without significant process changes since Li will undergo similar reactions to the transition metals in each process.
Due to its flexibility and simplicity of scaling, pyrometallurgy is one of the most widely used techniques for lithium-ion battery recycling, including by companies like Umicore, Sony, and GEM. However, while pyrometallurgy produces less hazardous waste than hydrometallurgical processes, it suffers from both high capital costs and high energy use, as well as substantial process-related CO₂ emissions.

Direct recycling

Direct recycling is an emerging battery recycling method that focuses on directly regenerating cathode materials without damaging the crystal structure. This is distinct from existing hydro- and pyrometallurgical methods, which break down the cathode into precursors and require subsequent processing to regenerate cathode materials. Maintaining the cathode structure represents an important increase in efficiency, since it produces a higher-value product than other recycling methods. In order to perform direct recycling, the cathode "black mass" must be separated from other battery components. Traditional separation methods, primarily battery shredding, are insufficient, as they introduce impurities into the cathode. Alternative separation methods include the use of solvents to recover the black mass. Many of the organic solvents investigated for this process are toxic and pose hazards to both humans and the environment. Identifying safer solvents which can effectively separate the black mass is a topic of current research. Once the cathode black mass is obtained, the material undergoes relithiation to reintroduce lithium which is "lost" during battery use and restore the cathode to its original capacity. This relithiation process can be carried out via several different methods, including solid state, electrochemical, or solution-based relithiation. While direct recycling is not yet commercialized, research indicates that it can restore cathode materials to their original electrochemical capacity and performance.