Novel strategy to make fast-charging solid-state batteries
In a breakthrough, researchers at the Indian Institute of Science (IISc) and their collaborators have discovered how next-generation solid-state batteries fail and devised a novel strategy to make these batteries last longer and charge faster.
Solid-state batteries are poised to replace the lithium-ion batteries found in almost every portable electronic device. But on repeated or excessive use, they develop thin filaments called “dendrites” which can short-circuit the batteries and render them useless.
In a new study published in Nature Materials, the researchers have identified the root cause of this dendrite formation—the appearance of microscopic voids in one of the electrodes early on. They also show that adding a thin layer of certain metals to the electrolyte surface significantly delays dendrite formation, extending the battery’s life and enabling it to be charged faster.
Conventional lithium-ion batteries—the kind that you might find in your smartphone or laptop—contain a liquid electrolyte sandwiched between a positively charged electrode (cathode) made of a transition metal (such as iron and cobalt) oxide and a negatively charged electrode (anode) made of graphite. When the battery is charging and discharging (using up power), lithium ions shuttle between the anode and cathode in opposite directions. These batteries have a major safety issue—the liquid electrolyte can catch fire at high temperatures. Graphite also stores much less charge than metallic lithium.
A promising alternative, therefore, is solid-state batteries that switch out the liquid for a solid ceramic electrolyte and swap graphite with metallic lithium. Ceramic electrolytes perform even better at higher temperatures, which is especially useful in tropical countries like India. Lithium is also lighter and stores more charge than graphite, which can significantly cut down the battery cost.
“Unfortunately, when you add lithium, it forms these filaments that grow into the solid electrolyte, and short out the anode and cathode,” explains Naga Phani Aetukuri, Assistant Professor in the Solid State and Structural Chemistry Unit (SSCU) and corresponding author of the study.
To investigate this phenomenon, Aetukuri’s Ph.D. student, Vikalp Raj, artificially induced dendrite formation by repeatedly charging hundreds of battery cells, slicing out thin sections of the lithium-electrolyte interface, and peering at them under a scanning electron microscope. When they looked closely at these sections, the team realized that something was happening long before the dendrites formed—microscopic voids were developing in the lithium anode during discharge. The team also computed that the currents concentrated at the edges of these microscopic voids were about 10,000 times larger than the average currents across the battery cell, which was likely creating stress on the solid electrolyte and accelerating the dendrite formation.
“This means that now our task to make very good batteries is very simple,” says Aetukuri. “All that we need is to ensure that the voids don’t form.”
To ensure this, the researchers introduced an ultrathin layer of a refractory metal—a metal that is resistant to heat and wear—between the lithium anode and solid electrolyte. “The refractory metal layer shields the solid electrolyte from the stress and redistributes the current to an extent,” says Aetukuri. He and his team collaborated with researchers at Carnegie Mellon University in the US, who carried out computational analysis which clearly showed that the refractory metal layer indeed delayed the growth of microscopic lithium voids.
Applying extreme pressure that can push lithium against the solid electrolyte can prevent voids and delay dendrite formation, but that may not be practical for everyday applications. Other researchers have also proposed the idea of using metals like aluminum that alloy or mix well with lithium at the interface. But over time, this metal layer blends with lithium, becoming indistinguishable, and does not prevent dendrite formation. “What we are saying is different,” explains Raj. “If you use a metal like tungsten or molybdenum that doesn’t alloy with lithium, the performance which you get from the cell is even better.”
The researchers say that the findings are a critical step forward in realizing practical and commercial solid-state batteries. Their strategy can also be extended to other types of batteries that contain metals like sodium, zinc and magnesium.
Reactive electrolyte additives improve lithium metal battery performance
Naga Aetukuri, Direct correlation between void formation and lithium dendrite growth in solid-state slectrolytes with interlayers, Nature Materials (2022). DOI: 10.1038/s41563-022-01264-8. www.nature.com/articles/s41563-022-01264-8
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