SBIR-STTR Award

New Electrolytes for Lithium-ion Cells
Award last edited on: 12/16/2013

Sponsored Program
SBIR
Awarding Agency
DOE
Total Award Amount
$1,099,257
Award Phase
2
Solicitation Topic Code
-----

Principal Investigator
Konstantin K Tikhonov

Company Information

Leyden Energy Inc (AKA: Mobius Power Inc)

46840 Lakeview Boulevard
Fremont, CA 94538
   (510) 933-3800
   info@leydenenergy.com
   www.leydenenergy.com
Location: Single
Congr. District: 17
County: Alameda

Phase I

Contract Number: ----------
Start Date: ----    Completed: ----
Phase I year
2010
Phase I Amount
$99,273
Commercially available lithium-ion cells use an electrolyte containing a mixture of organic carbonate solvents combined with lithium hexafluorophosphate (LiPF6). These electrolytes have significant disadvantages limiting the performance and safety of lithium-ion batteries. First, the solvents are volatile and flammable, leading to safety issues during production, storage and use of batteries and their behavior under abuse conditions. Second, LiPF6 is not hydrolytically or thermally stable in organic carbonates, leading to degradation of electrolyte, rise in electrode/electrolyte interface impedance, dissolution of active cathode materials and limited battery life. Thirdly, present electrolyte solutions appear to be reactive towards cathode materials at high voltages, which contribute to battery performance deterioration. It also prevents further development of future higher energy cells with 5V cathode materials. Finally, present electrolyte formulations are always a compromise; no one mixture of the solvents has been shown to work well at both low and high temperatures. Performance and safety issues associated with LiPF6 salt in organic carbonates electrolytes are magnified in case of batteries for automotive applications, where the requirements for both performance and safety are more stringent due to the larger batteries used and longer battery calendar and cycle life expected. We propose a novel lithium-ion battery electrolyte composed of a thermally stable lithium imide salt and non-flammable non-carbonate solvents. Use of this advanced electrolyte is coupled by employment of graphite foil as a cathode current collector, which unlike aluminum, does not corrode in lithium imide solutions. Commercial Applications and Other

Benefits:
Success of this program will lead to new generation of lithium-ion cells. These new cells will be much safer, due to significantly improved stability and non-flammability of electrolyte, and operate longer, both with respect to calendar and cycle life at higher temperatures. Energy density of the cells will increase as the new electrolyte will allow the use of higher voltage electrode materials. The new cells will find use in battery packs for many applications, including HEV, PHEV and EV. Safer, longer lasting batteries will in turn help accelerate the growth of this market and the acceptance of these new vehicles in the marketplace.

Phase II

Contract Number: ----------
Start Date: ----    Completed: ----
Phase II year
2011
Phase II Amount
$999,984
Commercially available lithium-ion cells use electrolytes containing a mixture of organic carbonate solvents combined with lithium hexafluorophosphate salt. These electrolytes have significant disadvantages limiting the performance and safety of large li-ion batteries for automotive applications: regular electrolytes are flammable and the instability of the salt causes battery performance degradation and limits the cycle life. We propose to develop a novel Li-ion battery electrolyte composed of thermally stable lithium imide salt and non-flammable solvents. Use of this advanced electrolyte is coupled by employment of graphite foil as a cathode current collector, which unlike aluminum, does not corrode in lithium imide salts solutions. During our Phase I effort we prepared and tested lithium imide-based electrolyte formulations incorporating 80% of non-flammable components, such as fluorinated ethers and ionic liquids, and demonstrated drastically improved safety in 2.4Ah pouch cells with cathodes coated on graphite foil current collector. During the Phase II effort we will expand our development into a number of promising non-flammable fluorinated solvents and imide anion ionic liquids. We will optimize electrolyte formulations and overall cell design to meet rate capability requirements. New electrolytes will be evaluated for performance and safety in large 10Ah pouch cells designed for automotive applications. Commercial Applications and Other

Benefits:
Success of this program will lead to new generation of safer, longer lasting Li-ion cells. These Li-ion batteries will find use in many applications, including HEV, PHEV and EV. That will in turn help accelerate the growth of this market and the acceptance of these new vehicles by the buying public.