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High Energy Density Nanocomposite Based on Tailored Surface Chemistry

Award Information
Agency: Department of Defense
Branch: Air Force
Contract: FA8650-10-M-2115
Agency Tracking Number: F09B-T05-0170
Amount: $99,960.00
Phase: Phase I
Program: STTR
Solicitation Topic Code: AF09-BT05
Solicitation Number: 2009.B
Solicitation Year: 2009
Award Year: 2010
Award Start Date (Proposal Award Date): 2010-04-28
Award End Date (Contract End Date): 2011-02-01
Small Business Information
3921 Academy Parkway North, NE
Albuquerque, NM 87109
United States
DUNS: 055145320
HUBZone Owned: No
Woman Owned: No
Socially and Economically Disadvantaged: No
Principal Investigator
 Kirk Slenes
 Vice President Capacitance Products
 (505) 342-4437
Business Contact
 Rodney Kreutzian
Title: Contracts Manager
Phone: (505) 342-4471
Research Institution
 University of Connecticut
 Ramamurthy Ramprasad
97 N. Eagleville Rd, Unit 3136
Storrs, CT 6269
United States

 (860) 486-4102
 Nonprofit College or University

High energy density capacitors are required for practical implementation of GW-class pulse power loads. In response to this need, TPL has established unique dielectric and capacitor capabilities. Revolutionary materials, designs and manufacturing process have been developed for power sources that have potential for an order of magnitude reduction in mass and volume relative to current commercially available systems. The technology is based on novel nanocomposite formulations that can be reliably formed into capacitors of complex shape and efficiently scaled for system integration. At present, TPL’s nanocomposite capacitors are capable of delivering the necessary sub-microsecond power with an energy density greater than any established technology. The proposed development will focus on advancing this technology by investigating nanopowder surface chemistries for increased composite voltage stress capability and energy density. Doping processes developed by TPL for ceramic capacitors will be applied to modifying titanate nanopowders to achieve tailored vacancy structures and charge transfer behavior. Experimental data will be acquired on capacitors and reconciled against theoretical, atomic-scale modeling at University of Connecticut. It is the overall program objective to establish a predictive model for charge behavior at particle-polymer interfaces and define an approach to delivering capacitors that meet Air Force requirements. BENEFIT: Successful completion of the proposed program will benefit development in several defense related power conditioning, control electronics and directed energy systems. High energy electrical storage systems with reduced size and weight are required for applications including: high energy laser, high power microwave, electric armor, electric guns, electric launch, particle accelerators and ballistic missile applications.

* Information listed above is at the time of submission. *

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