No Overcharging Here

Organization: Argonne National Laboratory (U.S. Dept. of Energy), A123 Systems LLC
Co-Developer(s): Khalil Amine, Principal Developer, Argonne National Laboratory, Tony Gozdz, Principal Developer, A123 Systems LLC, Gregory Krumdick, Principal Developer, Argonne National Laboratory, Zhengcheng Zhang, Principal Developer, Argonne National Laboratory, Trev
Year: 2014

2014 R&D 100 Winner Lithium-ion batteries are the most widely adopted power source for portable electronic devices including electric vehicles (EV). While having many advantages, the issue of safety continues to plague this technology, particularly of the battery’s inherent flammability, which can be exacerbated by overcharging during use.

Methods for overcharge protection have been sought for decades, using cell chemistry instead of electronics. The goal has been to develop a substance that dissolves in the electrolyte of a lithium-ion cell, remains inert during normal operation, becomes activated as overcharging begins and curtails the overcharging process by removing excess charges as they arrive at the cathode. Efforts at devising such a material that satisfies all of the requirements for use in practical lithium-ion battery cells designed to power electric vehicles have met with limited success until Argonne National Laboratory’s breakthrough in synthesizing 1,3-di-tert-butyl-2,4-bis(methoxyethoxy)benzene—ANL-RS2, in Argonne’s nomenclature.

Thorough testing by A123 Systems LLC has shown that ANL-RS2 Advanced Redox Shuttle Additive is a highly reliable and high-performance electrolyte additive for EV battery cells using LiFePO4 as the cathode material. When dissolved in the electrolyte of a LiFePO4-based lithium-ion battery cell, the ANL-RS2 Redox Shuttle Additive remains inert until the potential of the cell increases from 3.6 to 3.9 V during an overcharging event. At that point, ANL-RS2 becomes activated and is able to accept excess charges from the cathode and transport them to the anode, thereby accomplishing efficient overcharge protection by providing an internal electrical path for the excess charges arriving at the cathode.

Technology Redox shuttle additive

DevelopersArgonne National LaboratoryA123 Systems LLC

Development Team

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Argonne National Laboratory's ANL-RS2 Advanced Redox Shuttle Additive development team (l-r): Gregory Krumdick, Lu Zhang, Zhengcheng (John) Zhang, Trevor Dzwiniel and Khalil Amine.

 

 

 

 

 

 

 

 

 

 

 

 

 

The ANL-RS2 Advanced Redox Shuttle Additive Development Team Khalil Amine, Principal Developer, Argonne National Laboratory Tony Gozdz, Principal Developer, A123 Systems LLC Gregory Krumdick, Principal Developer, Argonne National Laboratory Zhengcheng Zhang, Principal Developer, Argonne National Laboratory Trevor Dzwiniel, Argonne National Laboratory Krzysztof Pupek, Argonne National Laboratory Lu Zhang, Argonne National Laboratory