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Caltech

MCE Ph.D. Thesis Seminar

Wednesday, April 22, 2015
1:00pm to 2:00pm
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Dendrites Inhibition in Rechargeable Lithium Metal Batteries
Asghar Aryanfar, Graduate Student, Mechanical and Civil Engineering, California Institute of Technology,

LOCATION: Salvatori Conference Room, 365 South Mudd

The specific high energy and power capacities of rechargeable lithium metal (Li0) batteries are ideally suited to portable devices and are valuable as storage units for intermittent renewable energy sources. Lithium, the lightest and most electropositive metal, would be the optimal anode material for rechargeable batteries if it were not for the fact that such devices fail unexpectedly by short-circuiting via the dendrites that grow across electrodes upon recharging. This phenomenon poses a major safety issue because it triggers a series of adverse events that start with overheating, potentially followed by the thermal decomposition and ultimately the ignition of the organic solvents used in such devices.

In this thesis, we developed experimental platform for monitoring and quantifying the dendrite populations grown in a Libattery prototype upon charging under various conditions. We explored the effects of pulse charging in the kHz range and temperature on dendrite growth, and also on loss capacity into detached "dead" lithium particles.

Simultaneously, we developed a computational framework for understanding the dynamics of dendrite propagation. The coarse-grained Monte Carlo model assisted us in the interpretation of pulsing experiments, whereas MD calculations provided insights into the mechanism of dendrites thermal relaxation. 

For more information, please contact Lynn Seymour by phone at 626-395-4107 or by email at [email protected].