10:00 AM - 11:00 AM
David Mitlin, GE Chair in Energy Systems, Clarkson University, Potsdam, New York
Building 4100, Room J-302
Email: Jagjit Nanda Phone:
Banana peel pseudographite (BPPG) offers superb dual functionality for sodium ion battery (NIB) and lithium ion battery (LIB) anodes. The materials possess low surface areas (19 - 217 m2 g-1) and a relatively high electrode packing density (0.75 g cm-3 vs. ~ 1 g cm-3 for graphite). Tested against Na, BPPG delivers a gravimetric (and volumetric) capacity of 355 mAhg-1 (by active material ~ 700 mAh cm-3, by electrode volume ~ 270 mAh cm-3) after 10 cycles at 50 mAg-1. A nearly flat ~ 200 mAhg-1 plateau that is below 0.1 V, and a minimal charge/discharge voltage hysteresis, makes BPPG a direct electrochemical analogue to graphite but with Na. A charge capacity of 221 mAhg-1 at 500 mAg-1 is degraded by 7% after 600 cycles, while a capacity of 336 mAhg-1 at 100 mAg-1 is degraded by 11% after 300 cycles, in both cases with ~ 100% cycling coulombic efficiency. For LIB applications BPPG offers a gravimetric (volumetric) capacity of 1090 mAhg-1 (by material ~ 2200 mAh cm-3, by electrode ~ 900 mAh cm-3) at 50 mAg-1. The reason that BPPG works so well for both NIBs and LIBs is that it uniquely contains three essential features: a) dilated intergraphene spacing for Na intercalation at low voltages; b) highly accessible near-surface nanopores for Li metal filling at low voltages; and c) substantial defect content in the graphene planes for Li adsorption at higher voltages. The < 0.1 V charge storage mechanism is fundamentally different for Na versus for Li. A combination of XRD and XPS demonstrates highly reversible Na intercalation rather than metal underpotential deposition. By contrast, the same analysis proves the presence of metallic Li in the pores, with intercalation being much less pronounced.