New High-Performance Solid-State Battery Surprises the Engineers Who Created It

New Battery Technology Concept

Engineers have created a new battery that merges solid-state electrolyte and all-silicon anode technologies, forming a silicon all-solid-state battery. Early tests indicate it is safe, long-lasting, and energy-dense, promising applications in grid storage and electric vehicles.

Engineers create a high performance all-solid-state battery with a pure-silicon anode.

Engineers created a new type of battery that weaves two promising battery sub-fields into a single battery. The battery uses both a solid-state electrolyte and an all-silicon anode, making it a silicon all-solid-state battery. The initial rounds of tests show that the new battery is safe, long-lasting, and energy-dense. It holds promise for a wide range of applications from grid storage to electric vehicles. 

The battery technology is described in the September 24, 2021 issue of the journal Science. University of California San Diego nanoengineers led the research, in collaboration with researchers at LG Energy Solution. 

Silicon anodes are famous for their energy density, which is 10 times greater than the graphite anodes most often used in today’s commercial lithium-ion batteries. On the other hand, silicon anodes are infamous for how they expand and contract as the battery charges and discharges, and for how they degrade with liquid electrolytes. These challenges have kept all-silicon anodes out of commercial lithium-ion batteries despite the tantalizing energy density. The new work published in Science provides a promising path forward for all-silicon-anodes, thanks to the right electrolyte.

All-Solid-State Battery With a Pure-Silicon Anode

1) The all solid-state battery consists of a cathode composite layer, a sulfide solid electrolyte layer, and a carbon free micro-silicon anode. 2) Before charging, discrete micro-scale Silicon particles make up the energy dense anode. During battery charging, positive Lithium ions move from the cathode to the anode, and a stable 2D interface is formed. 3) As more Lithium ions move into the anode, it reacts with micro-Silicon to form interconnected Lithium-Silicon alloy (Li-Si) particles. The reaction continues to propagate throughout the electrode. 4) The reaction causes expansion and densification of the micro-Silicon particles, forming a dense Li-Si alloy electrode. The mechanical properties of the Li-Si alloy and the solid electrolyte have a crucial role in maintaining the integrity and contact along the 2D interfacial plane. Credit: University of California San Diego

“With this battery configuration, we are opening a new territory for solid-state batteries using alloy anodes such as silicon,” said Darren H. S. Tan, the lead author on the paper. He recently completed his chemical engineering PhD at the UC San Diego Jacobs School of Engineering and co-founded a startup UNIGRID Battery that has licensed this technology. 

Next-generation, solid-state batteries with high energy densities have always relied on metallic lithium as an anode. But that places restrictions on battery charge rates and the need for elevated temperature (usually 60 degrees Celsius/140 degrees Fahrenheit or higher) during charging. The silicon anode overcomes these limitations, allowing much faster charge rates at room to low temperatures, while maintaining high energy densities. 

The team demonstrated a laboratory scale full cell that delivers 500 charge and discharge cycles with 80% capacity retention at room temperature, which represents exciting progress for both the silicon anode and solid-state battery communities.

Silicon as an anode to replace graphite

Silicon anodes, of course, are not new. For decades, scientists and battery manufacturers have looked to silicon as an energy-dense material to mix into, or completely replace, conventional graphite anodes in lithium-ion batteries. Theoretically, silicon offers approximately 10 times the storage capacity of graphite. In practice however, lithium-ion batteries with silicon added to the anode to increase energy density typically suffer from real-world performance issues: in particular, the number of times the battery can be charged and discharged while maintaining performance is not high enough.  

Much of the problem is caused by the interaction between silicon anodes and the liquid electrolytes they have been paired with. The situation is complicated by large volume expansion of silicon particles during charge and discharge. This results in severe capacity losses over time. 

“As battery researchers, it’s vital to address the root problems in the system. For silicon anodes, we know that one of the big issues is the liquid electrolyte interface instability,” said UC San Diego nanoengineering professor Shirley Meng, the corresponding author on the Science paper, and director of the Institute for Materials Discovery and Design at UC San Diego. “We needed a totally different approach,” said Meng.

Indeed, the UC San Diego led team took a different approach: they eliminated the carbon and the binders that went with all-silicon anodes. In addition, the researchers used micro-silicon, which is less processed and less expensive than nano-silicon that is more often used.

An all solid-state solution

In addition to removing all carbon and binders from the anode, the team also removed the liquid electrolyte. Instead, they used a sulfide-based solid electrolyte. Their experiments showed this solid electrolyte is extremely stable in batteries with all-silicon anodes. 

“This new work offers a promising solution to the silicon anode problem, though there is more work to do,” said professor Meng, “I see this project as a validation of our approach to battery research here at UC San Diego. We pair the most rigorous theoretical and experimental work with creativity and outside-the-box thinking. We also know how to interact with industry partners while pursuing tough fundamental challenges.” 

Past efforts to commercialize silicon alloy anodes mainly focus on silicon-graphite composites, or on combining nano-structured particles with polymeric binders. But they still struggle with poor stability.

By swapping out the liquid electrolyte for a solid electrolyte, and at the same time removing the carbon and binders from the silicon anode, the researchers avoided a series of related challenges that arise when anodes become soaked in the organic liquid electrolyte as the battery functions. 

At the same time, by eliminating the carbon in the anode, the team significantly reduced the interfacial contact (and unwanted side reactions) with the solid electrolyte, avoiding continuous capacity loss that typically occurs with liquid-based electrolytes.

This two-part move allowed the researchers to fully reap the benefits of low cost, high energy, and environmentally benign properties of silicon.

Impact & Spin-off Commercialization

“The solid-state silicon approach overcomes many limitations in conventional batteries. It presents exciting opportunities for us to meet market demands for higher volumetric energy, lowered costs, and safer batteries especially for grid energy storage,” said Darren H. S. Tan, the first author on the Science paper. 

Sulfide-based solid electrolytes were often believed to be highly unstable. However, this was based on traditional thermodynamic interpretations used in liquid electrolyte systems, which did not account for the excellent kinetic stability of solid electrolytes. The team saw an opportunity to utilize this counterintuitive property to create a highly stable anode.

Tan is the CEO and co-founder of a startup, UNIGRID Battery, that has licensed the technology for these silicon all solid-state batteries.

In parallel, related fundamental work will continue at UC San Diego, including additional research collaboration with LG Energy Solution. 

“LG Energy Solution is delighted that the latest research on battery technology with UC San Diego made it onto the Journal of Science, a meaningful acknowledgment,” said Myung-hwan Kim, President and Chief Procurement Officer at LG Energy Solution. “With the latest finding, LG Energy Solution is much closer to realizing all-solid-state battery techniques, which would greatly diversify our battery product lineup.”

“As a leading battery manufacturer, LGES will continue its effort to foster state-of-the-art techniques in leading research of next-generation battery cells,” added Kim. LG Energy Solution said it plans to further expand its solid-state battery research collaboration with UC San Diego.

Reference: “Carbon-free high-loading silicon anodes enabled by sulfide solid electrolytes” by Darren H. S. Tan, Yu-Ting Chen, Hedi Yang, Wurigumula Bao, Bhagath Sreenarayanan, Jean-Marie Doux, Weikang Li, Bingyu Lu, So-Yeon Ham, Baharak Sayahpour, Jonathan Scharf, Erik A. Wu, Grayson Deysher, Hyea Eun Han, Hoe Jin Hah, Hyeri Jeong, Jeong Beom Lee, Zheng Chen and Ying Shirley Meng, 24 September 2021, Science.
DOI: 10.1126/science.abg7217

The study had been supported by LG Energy Solution’s open innovation, a program that actively supports battery-related research. LGES has been working with researchers around the world to foster related techniques. 

Authors: Darren H. S. Tan, Yu-Ting Chen, Hedi Yang, Wurigumula Bao, Bhagath Sreenarayanan, Jean-Marie Doux, Weikang Li, Bingyu Lu, So-Yeon Ham, Baharak Sayahpour, Jonathan Scharf, Erik A. Wu, Grayson Deysher, Zheng Chen and Ying Shirley Meng from the Department of NanoEngineering, Program of Chemical Engineering, and Sustainable Power & Energy Center (SPEC) University of California San Diego Jacobs School of Engineering; Hyea Eun Han, Hoe Jin Hah, Hyeri Jeong, Jeong Beom Lee, from LG Energy Solution, Ltd.

Funding: This study was financially supported by the LG Energy Solution company through the Battery Innovation Contest (BIC) program. Z.C. acknowledges funding from the start-up fund support from the Jacob School of Engineering at University of California San Diego. Y.S.M. acknowledges funding support from Zable Endowed Chair Fund.

8 Comments on "New High-Performance Solid-State Battery Surprises the Engineers Who Created It"

  1. Don’t care.
    Everyone is always surprised at this and that and yet NOTHING is on the market.

    Get back to us when it’s in the Register End Cap at Home Depot.

  2. Do care.

    All product development has phases. I appreciate being informed of promising scientific developments that may eventually make it to market.

  3. I care enough, it’s a good result and reflects well on LGe. Would be well late news if it were on the checkout end cap at a middling chain; let me know about the secret hardware store in Tesla and GM dealerships soon enough though, too. Red rock electroreduction is still hard; fun to think of doing it in a nanopowder loop.

  4. The team demonstrated a laboratory scale full cell that delivers 500 charge and discharge cycles with 80% capacity retention at room temperature, which represents exciting progress for both the silicon anode and solid state battery communities.

    At room temperature????? What car it going to operate at 72° at all times?

  5. This is another purely academic pursuit that will never have a practical application. If you read the full paper, the authors state that a minimum pressure of 7300 psi (50 MPa) is required, which completely rules out any EV application.

  6. Reading about this type of research is refreshing. Whether it goes into production or not, to have this info out there makes more options for the future. There is no magic bullet for scientific advances only building on existing knowledge

  7. 80% capacity remaining after 500 charge cycles… Isn’t that worse than existing batteries being used by Tesla?

  8. Keeping the carrot in front of the donkey is all I get from these articles.

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