Apr 24, 2024
1:45pm - 2:00pm
Room 432, Level 4, Summit
Gayea Hyun1,Myeong Hwan Lee1,Haodong Liu1,Shen Wang1,Victoria Petrova1,Ping Liu1
University of California San Diego1
Gayea Hyun1,Myeong Hwan Lee1,Haodong Liu1,Shen Wang1,Victoria Petrova1,Ping Liu1
University of California San Diego1
Rechargeable lithium-sulfur dioxide (Li-SO<sub>2</sub>) batteries are potentially of low-cost and high-energy density. The high SO<sub>2</sub> solubility in organic solvents has enabled cell operation under non-pressurized conditions. For example, superior electrochemical stability has been observed in carbonate-based electrolytes. However, most of the reports so far employ an “open cell configuration”, where continuous SO<sub>2</sub> supply is provided. The needed accessories, such as gas diffusion layers and Swagelok-type cell construction with heavy steel frames, and gas handling systems, greatly impede the development of practical high-energy-density batteries.<br/>Herein, we report our progress on understanding the behavior of electrolytes containing SO<sub>2</sub> within a closed system and to maximize the utilization of the active material. In comparison to other redox-active gases, SO<sub>2</sub> molecules, with their relatively high molecular weight (twice as heavy as O<sub>2</sub>) and polarity, not only suffer from slow diffusion (~0.7 times lower diffusion coefficient compared to that of O<sub>2</sub>) within the electrolyte but also exhibit a peculiar reverse osmotic behavior. When SO<sub>2</sub> is consumed in the electrolyte volume between the two electrodes, dissolved SO<sub>2</sub> in electrolyte outside the current path does not diffuse in. Instead, organic solvents are driven into the current path, leading to an evolution of SO<sub>2</sub> gas outside a cell stack. Our investigation confirmed that this behavior is driven by the molecular interactions between SO<sub>2</sub> and the organic solvents.<br/>Based on the above insights, we have designed electrochemical cells to strategically place all SO<sub>2</sub> containing electrolyte within the current path, leading to maximize utilization. Our optimized bobbin-type battery, in which the electrolyte containing SO<sub>2</sub> is entirely contained within the cell stack, has proven highly effective in maximizing discharge capacity. This configuration allowed us to achieve exceptional utilization (~73%) of SO<sub>2</sub> along with an acceptable E/C ratio (~13 g/Ah, with discharge capacities of 2639 mAh/g<sub>KB</sub> and 7.9 mAh/cm<sup>2</sup>). To further enhance the performance, we have developed a nanoporous lithium protective layer made of a composite of Nafion and alumina nanopowder, capable of retaining SO<sub>2</sub> reactant within the cell stack while minimizing continuous reactant loss from undesirable reactions with Li metal anode. In addition, we have achieved remarkable cycling stability by identifying catalysts to reduce side reactions and polarization on the cathode. This research sheds new light on the working mechanisms of the Li-SO<sub>2</sub> chemistry and points to its potential as a low-cost, sustainable battery.