News News
Contact us
  • Customer service number:64321087
  • Commercial service telephone:13918059423
  • Technical service telephone:13918059423
  • Contact person: Mr. Cui 
  • Service
  • Address: room 107, building 8, no. 100, guilin road, xuhui district, Shanghai

Solid-State Battery Breakthrough Promises Safer Energy Storage

The date of: 2023-11-15
viewed: 0

The breakthrough in solid-state batteries with a chloride-based electrolyte offers high ionic conductivity and improved safety over liquid electrolyte batteries.
The new technology uses cheaper, more abundant materials like zirconium, overcoming the challenges associated with rare earth metals in previous designs.
This development could accelerate the adoption of electric vehicles and other battery-powered devices, but challenges like generating capacity and grid capability for charging remain unaddressed.
Researchers announced a major breakthrough in the field of next-generation solid-state chloride-based solid electrolyte batteries. It is believed that their new findings will enable the creation of batteries that exhibit exceptional ionic conductivity.
The researchers led by Professor Kisuk Kang of the Center for Nanoparticle Research within the Institute for Basic Science (IBS), announced the major breakthrough with a research paper published in the journal Science.
A pressing concern with current commercial batteries their reliance on liquid electrolytes, which leads to flammability and explosion risks. Therefore, the development of non-combustible solid electrolytes is of paramount importance for advancing solid-state battery technology.
As the world gears up to regulate internal combustion engine vehicles and expand the use of electric vehicles in the ongoing global shift toward sustainable transportation, research into the core components of secondary batteries, particularly solid-state batteries, has gained significant momentum.
To make solid-state batteries practical for everyday use, it is crucial to develop materials with high ionic conductivity, robust chemical and electrochemical stability, and mechanical flexibility. While previous research successfully led to sulfide and oxide-based solid electrolytes with high ionic conductivity, none of these materials fully met all these essential requirements.
In the past, scientists have also explored chloride-based solid electrolytes, known for their superior ionic conductivity, mechanical flexibility, and stability at high voltages. These properties led some to speculate that chloride-based batteries are the most likely candidates for solid-state batteries. However, these hopes quickly died out, as the chloride batteries were considered impractical due to their heavy reliance on expensive rare earth metals, including yttrium, scandium, and lanthanide elements, as secondary components.
To address these concerns, the IBS research team looked at the distribution of metal ions in chloride electrolytes. They believed the reason trigonal chloride electrolytes can achieve low ionic conductivity is based on the variation of metal ion arrangements within the structure.
They first tested this theory on lithium yttrium chloride, a common lithium metal chloride compound. When the metal ions were positioned near the pathway of lithium ions, electrostatic forces caused obstruction in their movement. Conversely, if the metal ion occupancy was too low, the path for lithium ions became too narrow, impeding their mobility.
Building on these insights, the research team introduced strategies to design electrolytes in a way that mitigates these conflicting factors, ultimately leading to the successful development of a solid electrolyte with high ionic conductivity.
The group went further to successfully demonstrate this strategy by creating a lithium-metal-chloride solid-state battery based on zirconium, which is far cheaper than the variants that employ rare earth metals. This was the first instance where the significance of the metal ions arrangement on a material’s ionic conductivity was demonstrated.
This research brings to light the often-overlooked role of metal ion distribution in the ionic conductivity of chloride-based solid electrolytes. It is expected that the IBS Center’s research will pave the way for the development of various chloride-based solid electrolytes and further drive the commercialization of solid-state batteries, promising improved affordability and safety in energy storage.
Corresponding author Kisuk Kang stated, “This newly discovered chloride-based solid electrolyte is poised to transcend the limitations of conventional sulfide and oxide-based solid electrolytes, bringing us one step closer to the widespread adoption of solid-state batteries.”

Hot News / Related to recommend
  • 2024 - 07 - 19
    Click on the number of times: 0
    source: Purdue UniversityPurdue University engineers have developed a patent-pending method to synthesize high-quality, layered perovskite nanowires with large aspect ratios and tunable organic-inorga...
  • 2024 - 07 - 18
    Click on the number of times: 0
    source:Innovation newsnetworkThe Analysis Center is developing innovative new materials-characterisation technology and expanding the suite of analytical techniques available regionally to support REE...
  • 2024 - 07 - 17
    Click on the number of times: 1
    source: Lawrence Berkeley National LaboratoryThe element actinium was first discovered at the turn of the 20th century, but even now, nearly 125 years later, researchers still don't have a good gr...
  • 2024 - 07 - 17
    Click on the number of times: 0
    source:Songshan Lake Materials LaboratoryResearchers at Songshan Lake Materials Laboratory have made significant advances in sodium-ion battery (SIB) technology by improving cycling performance of the...
  • Copyright ©Copyright 2018 2020 Shanghai rare earth association All Rights Reserved Shanghai ICP NO.2020034223
    the host:Shanghai Association of Rare Earth the guide:Shanghai Development and Application Office of Rare Earth the organizer:Shanghai rare earth industry promotion center