Highly Conductive Polymer Electrolyte Impregnated 3d Li-Metal Negative Electrode

Award Information
Agency:
National Aeronautics and Space Administration
Amount:
$124,582.00
Program:
SBIR
Contract:
NNX14CC49P
Solitcitation Year:
2014
Solicitation Number:
N/A
Branch:
N/A
Award Year:
2014
Phase:
Phase I
Agency Tracking Number:
144514
Solicitation Topic Code:
Z1.02
Small Business Information
Xerion Advanced Battery
60 Hazlewood Drive, Champaign, IL, 61802-7460
Hubzone Owned:
N
Woman Owned:
N
Socially and Economically Disadvantaged:
N
Duns:
079248265
Principal Investigator
 Thuy Dang
 Senior Polymer Chemist
 (217) 265-5215
 t.dang@xerionbattery.com
Business Contact
 Justin Lenoff
Title: Business Official
Phone: (217) 265-5215
Email: j.lenoff@xerionbattery.com
Research Institution
 Stub
Abstract
XABC (Xerion Advanced Battery Corp) proposes a novel anode with three unique features, each designed to 1) control or 2) prevent dendrite growth. The first feature is a 95% porous electrode architecture. This electrode is an open-cell, nanostructured conductive foam whose internal structures are conformal coated with lithium metal. Dendrites growing outward from an internal pore surface will propagate until they come into contact with an opposing wall inside the foam and further growth is mechanically frustrated. This prevents dendrites from propagating external to the anode, as the dendrites would be trapped within the structure of the foam. The second feature is a five micron mask that, when applied to the surface of the 3d foam, prevents electrodeposition of lithium metal near the surface of the electrode, hence preventing growth of lithium dendrites near the surface. The third feature is a novel, highly conductive ionic fluid rigid-rod polymer composite expected to achieve a conductivity of 8.3x10^-3 S/cm^2. This polymer has already demonstrated protonic conductivity of 8.3x10^-3 S/cm^2 and must be modified for use in a lithium ion battery. Rigid-rod polymers have a tensile modulus that is 37x – 62x stronger than a standard polyethelyene solid polymer electrolyte. This strength may physically deter or altogether prevent the growth of lithium dendrites. XABC believes that the novel combination of these three unique features will enable the stable cycling of lithium metal in a secondary cell. For Phase I, XABC proposes to fabricate and test the effect of both the polymer and masked 3d foam on dendrite suppression. For Phase II, XABC proposes to fabricate fully functioning negative electrodes with the features above.

* information listed above is at the time of submission.

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