New Material Pushes Sodium-Ion Batteries To Phase Out Costly Lithium

Highlights :

  • It’s used in the battery cathode to provide record-high energy storage capacity, eliminating one of the bottlenecks of the emerging sodium-ion technology.
  • According to the scientists, once more research into efficient materials for sodium-ion batteries is conducted, they might well supersede lithium-ion ones.
New Material Pushes Sodium-Ion Batteries To Phase Out Costly Lithium Sodion Energy , AR4 Tie Up To Develop Sodium-Ion Batteries For India 

The researchers from Skoltech and Lomonosov Moscow State University have developed a material for sodium-ion batteries which offer an alternative to the increasingly expensive lithium-ion tech. In an official statement, the University said that the new material is a powder of sodium-vanadium phosphate fluoride with a particular crystal structure. It’s used in the battery cathode to provide record-high energy storage capacity, eliminating one of the bottlenecks of the emerging sodium-ion technology. The research findings are reported in Nature Communications.

The University says that relying on lithium alone is risky, because its chemicals are growing ever more expensive, their production is rather dirty, and the ore deposits are unevenly distributed around the world. One step down in the periodic table, the much more abundant alkali metal sodium lends itself as a possible alternative to lithium.

So far the sodium-ion battery tech is relatively new, and while the basic architecture of the battery cell is the same, different materials have to be used for the principal components. Among them, the cathode is crucial for battery characteristics. In their recent paper, Skoltech and MSU researchers came up with a new cathode material that ensures 10%-15% better battery energy density than the current top contender.

“Both our new material and the one the industry has recently deployed are called sodium-vanadium phosphate fluoride — they’re made of atoms of the same elements. What makes them different is how those atoms are arranged and in what ratio they are contained in the compound,” study co-author, Assistant Professor Stanislav Fedotov of Skoltech, said.

“Our material also compares well with the class of layered materials for cathodes: It provides roughly the same battery capacity and greater stability, which translates into longer life and higher cost-efficiency of the battery,” Fedotov went on. “Remarkably, even the theoretical predictions for the competing materials fall short of the practical performance of ours, and this is far from trivial, because the theoretical potential is never fully realized.”

According to the scientists, once more research into efficient materials for sodium-ion batteries is conducted, they might well supersede lithium-ion accumulators in heavy electric vehicles and also stationary energy storage at wind and solar farms.

Hard Science Shows The Way

Semyon Shraer, lead author of the paper, said the researchers relied on hard science, using the fundamental laws and principles of solid-state chemistry to arrive at the material with desired properties.

“Theoretical considerations led us to the basic formula for a material that might provide high energy storage capacity,” he went on. “We then needed to determine which crystal structure would unlock that potential. The one we chose is known as the KTP-type framework, and it comes from nonlinear optics — it’s not really common for battery engineering. After careful thinking and theoretization we realized that this particular compound with that particular crystal structure should work. Then we managed to synthesize it via low-temperature ion exchange. And there it is, with its superior characteristics now confirmed by an experiment.”

The global EV battery market is expected to grow to $559 billion by the end of this decade according to Precedence Research with a CAGR of over 32 per cent. The current market is overwhelmingly dependent on lithium-ion batteries, that is not just very costly but also environmentally devastating.  The invention by Skoltech and Lomonosov Moscow State University research team looks like coming with a promise.

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