WEST LAFAYETTE, Ind. – A new electrode design for lithium-ion batteries has been shown to potentially reduce the charging time from hours to minutes by replacing the conventional graphite electrode with a network of tin-oxide nanoparticles.
Batteries have two electrodes, called an anode and a cathode. The anodes in most of today’s lithium-ion batteries are made of graphite.
The theoretical maximum storage capacity of graphite is very limited, at 372 milliamp hours per gram, hindering significant advances in battery technology, said Vilas Pol, an associate professor of chemical engineering at Purdue University.
The researchers have performed experiments with a “porous interconnected” tin-oxide based anode, which has nearly twice the theoretical charging capacity of graphite. The researchers demonstrated that the experimental anode can be charged in 30 minutes and still have a capacity of 430 milliamp hours per gram (mAh g−1), which is greater than the theoretical maximum capacity for graphite when charged slowly over 10 hours.
This schematic diagram depicts the concept for a new electrode design for lithium-ion batteries that has been shown to potentially reduce the charging time from hours to minutes by replacing the conventional graphite electrode with a network of tin-oxide nanoparticles. (Purdue University image/Vinodkumar Etacheri)
The anode consists of an “ordered network” of interconnected tin oxide nanoparticles that would be practical for commercial manufacture because they are synthesized by adding the tin alkoxide precursor into boiling water followed by heat treatment, Pol said.
“We are not using any sophisticated chemistry here,” Pol said. “This is very straightforward rapid ‘cooking’ of a metal-organic precursor in boiling water. The precursor compound is a solid tin alkoxide – a material analogous to cost-efficient and broadly available titanium alkoxides. It will certainly become fully affordable in the perspective of broad scale application mentioned by collaborators Vadim G. Kessler and Gulaim A. Seisenbaeva from the Swedish University of Agricultural Sciences.”
Findings are detailed in a paper published in November in the journal Advanced Energy Materials.
When tin oxide nanoparticles are heated at 400 degrees Celsius they “self-assemble” into a network containing pores that allow the material to expand and contract, or breathe, during the charge-discharge battery cycle.
“These spaces are very important for this architecture,” said Purdue postdoctoral research associate Vinodkumar Etacheri. “Without the proper pore size, and interconnection between individual tin oxide nanoparticles, the battery fails.”
The research paper was authored by Etacheri; Swedish University of Agricultural Sciences researchers Gulaim A. Seisenbaeva, Geoffrey Daniel and Vadim G. Kessler; James Caruthers, Purdue’s Gerald and Sarah Skidmore Professor of Chemical Engineering; Jeàn-Marie Nedelec, a researcher from Clermont Université in France; and Pol.
Electron microscopy studies were performed at the Birck Nanotechnology Center in Purdue’s Discovery Park. Future research will include work to test the battery’s s ability to operate over many charge-discharge cycles in fully functioning batteries.
Ordered Network of Interconnected SnO2 Nanoparticles for Excellent Lithium-Ion Storage
Vinodkumar Etacheri, Gulaim A. Seisenbaeva, James Caruthers, Geoffrey Daniel, Jean-Marie Nedelec, Vadim G. Kessler, and Vilas G. Pol*
An ordered network of interconnected tin oxide (Tin oxide) nanoparticles with a unique 3D architecture and an excellent lithium-ion (Li-ion) storage performance is derived for the first time through hydrolysis and thermal self assembly of the solid alkoxide precursor. Mesoporous anodes composed of these ~9 nm-sized Tin oxide particles exhibit substantially higher specific capacities, rate performance, coulombic efficiency, and cycling stabilities compared with disordered nanoparticles and commercial Tin oxide. A discharge capacity of 778 mAh g–1, which is very close to the theoretical limit of 781 mAh g–1, is achieved at a current density of 0.1 C. Even at high rates of 2 C (1.5 A g–1) and 6 C (4.7 A g–1), these ordered Tin oxide nanoparticles retain stable specific capacities of 430 and 300 mAh g–1, respectively, after 100 cycles. Interconnection between individual nanoparticles and structural integrity of the Tin oxide electrodes are preserved through numerous charge–discharge process cycles. The significantly better electrochemical performance of ordered Tin oxide nanoparticles with a tap density of 1.60 g cm–3 is attributed to the superior electrode/electrolyte contact, Li-ion diffusion, absence of particle agglomeration, and improved strain relaxation (due to tiny space available for the local expansion). This comprehensive study demonstrates the necessity of mesoporosity and interconnection between individual nanoparticles for improving the Li-ion storage electrochemical performance of Tin oxide anodes.