Boron-Doped Carbon Scaffold Hosts for Li Metal Batteries

Abstract

Lithium metal anodes offer the promise of higher energy density batteries. However, the formation of lithium dendrites due to non-uniform plating and stripping of the lithium metal has proven to be a major hurdle for this technology, decreasing the lifetime of the device and causing safety hazards. Utilizing a carbon scaffold host for the lithium metal anode can limit dendrite formation by providing a more uniform electric field and numerous lithium nucleation sites to encourage uniform plating and stripping. In this poster, we present our work developing carbon scaffold hosts for lithium metal anodes. We synthesized scaffolds with various architectures and microstructures using different carbon materials. Our atomistic simulations demonstrated that the addition of boron to the carbon results in stronger binding of lithium to the carbon surface, further improving the lithiophilicity. Therefore, we also prepared boron-doped carbon scaffolds to test this experimentally. Boron was introduced using boric acid and incorporated into the carbon structure during carbonization under nitrogen, and these samples were characterized by XPS, SEM, and BET to try and correlate scaffold properties with performance. In addition, we are investigating other dopants (such as nitrogen), which have also been reported to increase the lithiophilicity of carbon materials. Utilizing these doped carbon scaffolds can help increase the lifetime of lithium metal batteries by improving the cycling uniformity.This work was performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344