Scientists have created a type of up-and-coming lithium battery that can run on air – rather than pure oxygen – for hundreds of charging cycles.
Electric vehicles powered by lithium-air battery would be able to travel further on a single charge as these batteries can hold more energy that a lithium-ion battery of the same weight. However, lithium-air batteries have yet to run on air for any length of time. The problem is nitrogen, carbon dioxide and water vapour in air react with ions at the battery’s electrodes, forming deposits that quickly reduce each electrode’s ability to hold charge.
Since oxygen is the only component of air needed for productive electrochemical reactions in lithium-air battery, researchers feed it, rather than air, into a battery. While this eliminates side reactions, it’s not practical for further applications: delivering pure oxygen to a car battery could create safety issues.
To create a long-lived lithium battery that runs on air, Amin Salehi-Khojin, at the University of Illinois at Chicago, US, and his colleagues designed the electrolyte in their battery to minimise problematic side reactions. To make the battery anode, the researchers electrochemically deposited lithium carbonate and carbon onto lithium chips. This coating allowed lithium ions to pass through while preventing carbon dioxide, oxygen, nitrogen and water from reaching the reactive lithium at the electrode surface.
The researchers minimised side reactions at the cathode by choosing a material and electrolyte that mediated reactions only between lithium and oxygen during charging and discharging. They made the cathode using nanoflakes of molybdenum disulfide, which catalyses the formation of Li2O2 during charging along with its decomposition during discharging.
The researchers also filled the battery with an electrolyte containing a lithium salt dissolved in a mixture of dimethyl sulfoxide and an iconic liquid.
The structure of Li2O2 formed at the cathode can influence its tendency to collect water and carbon dioxide, which react with lithium ions to form deposits of lithium hydroxide and carbonate that clog reactive sites on the cathode. When the researchers examined a cathode discharging in the mixed electrolyte using transmissions electron microscopy, they saw a thin film of Li2O2 on its surface. Computer models suggested that carbon dioxide and water do not stick to this thin film, thus reducing the opportunity to form cathode-clogging salts.
‘The components of the battery isolate nitrogen, carbon dioxide and water vapour so they can’t participate in unwanted side reactions,’ explains Salehi-Khojin.
A lithium-air battery assembled from the designed electrodes and electrolyte ran for 700 charging cycles in simulated air. A battery created with an uncoated anode and the same cathode electrolyte failed after 11.
Interpreting cycle life can be difficult for lithium-air batteries, notes Venkat Viswanathan, at Carnegie Mellon University, US. A common way to determine cycle life in lithium-ion batteries involves measuring charge delivered with each battery charge and discharge. However, for lithium-air batteries, those delivered charges can also come from many other reactions other than the desired one between lithium and oxygen. Viswanathan wonders how many parasitic processes are happening in this battery that could artificially enhance its cycle life, and minimise those parasitic processes will be crucial to making a commercially viable long-lasting lithium-air battery.
Taken from Chemistry World May 2018 edition
