Loren Data's SAM Daily™

SAMDAILY.US - ISSUE OF JULY 01, 2023 SAM #7886
SPECIAL NOTICE

99 -- TECHNOLOGY/BUSINESS OPPORTUNITY ??Advanced Battery Manufacturing Technologies?

Notice Date

6/29/2023 12:12:15 PM
 

Notice Type

Special Notice
 

NAICS

335910 —
 

Contracting Office

LLNS � DOE CONTRACTOR Livermore CA 94551 USA
 

ZIP Code

94551
 

Solicitation Number

IL-13434Plus
 

Response Due

7/29/2023 12:00:00 PM
 

Archive Date

08/13/2023
 

Point of Contact

Jared Lynch, Phone: 9254226667, Charlotte Eng, Phone: 9254221905
 

E-Mail Address

lynch36@llnl.gov, eng23@llnl.gov
(lynch36@llnl.gov, eng23@llnl.gov)
 

Description

Opportunity: Lawrence Livermore National Laboratory (LLNL), operated by the Lawrence Livermore National Security (LLNS), LLC under contract no. DE-AC52-07NA27344 (Contract 44) with the U.S. Department of Energy (DOE), is offering the opportunity to enter into a collaboration to further develop or fully license its technology suite for advanced manufacturing techniques of solid-state electrolytes and electrode materials for either all-solid-state lithium batteries or lithium ion batteries using laser processing or powder-atomic layer deposition methods. Background: Lithium-ion batteries (LIBs) are commonly used for portable electronics and electric vehicles (EVs) because of their high energy density, no memory effect on recharge, and a low self-discharge.� Accelerated adoption of LIBs for EVs and grid storage requires lowering battery manufacturing costs while retaining high power and energy densities.� One of the drawbacks of LIBs, however, is the electrolyte used is flammable, and presents explosion and fire risk.� Hence, there was need for developing next generation solid-state batteries (SSBs) that replace the flammable liquid electrolyte with a solid-state electrolyte (SSE), which may be composed of ceramic or polymeric material.�� SSBs are expected to eliminate fire concerns, extend the life of batteries, speed charging, and improve capacity.� It is anticipated that during the transition from traditional LIBs to SSBs there will likely be a period where both energy storage devices co-exist in the marketplace and thus both battery types will require continued improvements in electrode and electrolyte component manufacturing. For LIBs, a significant contributor to their total cost is cell manufacturing, particularly, the electrode processing step. Solvents used during processing require long drying times and drives greater energy consumption. Moreover, many solvents such as NMP are toxic, requiring expensive recovery and safety protocols.� Accelerated adoption of LIBs in electric vehicles (EVs) and grid storage requires lowering battery manufacturing costs while retaining high power and energy densities.� One promising method to achieve higher power density is through structured electrode designs with fast ionic and electronic transport channels.� Various technologies have been proposed, such as casting head designs, laser hole-drilling, 3D scaffolds with loaded active materials, and 3D printing. However, the use of solvent, the low integration ability, and high processing cost continue to be issues with these various processes. For SSBs, garnet-type Li7La3Zr2O12 (LLZO) and its doped analogs are very promising SSEs because of their high ionic conductivity and large stability voltage window; processing these SSEs are critical to the performance of the SSBs. However, widespread adoption of state-of-the-art fabrication of SSEs for commercial production (e.g., furnace, spark plasma, or flash sintering, hot pressing) has been limited because these methods have complex steps, are energy and time intensive, and difficult to achieve economy of scale. Furthermore, garnet-type SSEs can be challenging to synthesize, particularly on an industrial scale due to the 1) high sintering temperature needed for their densification, which can lead to severe Li loss and 2) formation of an insulating lithium carbonate surface contaminant that hinders performance. Description: To address many of the aforementioned challenges of manufacturing LIBs and SSBs, LLNL researchers have developed a number of inventions that offer proposed solutions for their components: For LIB and SSB electrodes, LLNL researchers have developed a laser powder-bed fusion (L-PBF) approach for their manufacture that is solvent-free. Additionally, L-PBF allows for optimized structured designs that can facilitate Li-ion transport through thick electrodes. This novel method has excellent scalability and high production rates, which could significantly reduce manufacturing cost, energy consumption, and environmental impact of LIBs. To remove the unwanted lithium carbonate layer that develops on LLZO when its surface is exposed to air, LLNL researchers have developed a method using a diode laser system to sinter the SSE followed by a pulsed laser ablation step to remove the inhibitory lithium carbonate surface impurity. LLNL researchers have also made advances in improving the electrochemical performance of LLZO-based SSE by using an atomic layer deposition (ALD) assisted method to modify the surface of LLZO precursor powders. The powdered SSE materials (e.g., pure or doped LLZO) can be mixed with other additives while the coating can be composed of Al2O3 or other oxides and its thickness can be precisely controlled.� The surface-modified powders can then be prepared for sintering (or mixed with cathode materials for co-sintering) to obtain a product that can be used directly for the assembly of solid-state batteries. Advantages/Benefits:� Laser processing provides a bundle of solutions to tackle the challenges of manufacturing components for next generation lithium-based batteries: L-PBF production of LIBs or SSBs is a solvent-free process that has higher production rates.� Additionally, performance and customization of these batteries can be achieved using this method as it allows for the creation of complex 3D structures, multilayers, and chemical/morphological gradients at high resolution. The printed electrodes also have improved bonding characteristics as compared to slurry-made thick electrodes. For the manufacture of electrodes, rapid heating via laser sintering can be used to promote SSE densification while minimizing Li loss. Laer sintering provides simplified synthetic procedures for manufacturing diverse form factors at relatively lower cost and energy consumption compared to other SSE manufacturing techniques. Using laser systems allows for flexibility and complexity in the manufacturing of components (e.g., fine tuning of ceramic microstructures that enables unique mechanical and functional properties).� Besides its use in sintering, laser surface treatments can improve mechanical strength and charge transfer at the electrode-electrolyte interface as well as mitigate lithium deposition-induced cracking. In addition, to the novel laser-based manufacturing methods, LLNL also developed a straightforward approach to enhance SSE precursor powders using ALD.� The coating improves energy densities and performance by increasing wettability towards the Li metal electrode and reducing charge transfer resistance. Potential Applications:� LIB and SSM manufacturing SSEs manufacturing Additive manufacturing of next generation batteries. Development Status:� Current stage of technology development:� TRL 2-3 depending on the technology LLNL has filed for patent protection on this invention. U.S. Patent Application No. 2021/0245296 Systems and methods for laser processing of solid-state batteries published 8/12/2021. U.S. Patent Application No. US2022/0336847 Solid state electrolytes published 10/20/2022. U.S. Patent Application No. 18/202739 Systems and methods for laser additive for structured battery components filed on 5/26/2023 LLNL is seeking industry partners with a demonstrated ability to bring such inventions to the market. Moving critical technology beyond the Laboratory to the commercial world helps our licensees gain a competitive edge in the marketplace. All licensing activities are conducted under policies relating to the strict nondisclosure of company proprietary information.� Please visit the IPO website at https://ipo.llnl.gov/resources for more information on working with LLNL and the industrial partnering and technology transfer process. Note:� THIS IS NOT A PROCUREMENT.� Companies interested in commercializing LLNL's Advanced Battery Manufacturing Technologies should provide an electronic OR written statement of interest, which includes the following: Company Name and address. The name, address, and telephone number of a point of contact. A description of corporate expertise and/or facilities relevant to commercializing this technology. Please provide a complete electronic OR written statement to ensure consideration of your interest in LLNL's Advanced Battery Manufacturing Technologies. The subject heading in an email response should include the Notice ID and/or the title of LLNL�s Technology/Business Opportunity and directed to the Primary and Secondary Point of Contacts listed below. Written responses should be directed to: Lawrence Livermore National Laboratory Innovation and Partnerships Office P.O. Box 808, L-779 Livermore, CA� 94551-0808 Attention:�� IL-13434Plus
 

Web Link

SAM.gov Permalink
(https://sam.gov/opp/5aa65ba7b08a42e283e75b91afc12e86/view)
 

Place of Performance

Address: Livermore, CA, USA

Country: USA
 

Record

SN06731744-F 20230701/230629230048 (samdaily.us)
 

Source

SAM.gov Link to This Notice
(may not be valid after Archive Date)

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