Lithium-ion secondary batteries (hereafter “LIB”) have a high storable energy density and are suitable for miniaturization and larger capacities, so they are increasingly used not only in mobile phones and computers, but also for electric vehicles and renewable energy power storage. In order to use LIB for long times, it is necessary to suppress deterioration due to repeated charging and discharging.

LIBs are charged by the movement of lithium ions from the cathode material into the anode material such as graphite. Therefore, analysis of the causes of degradation of charging capacity has called for acquisition of information such as the type and density of crystals that hold the lithium ions in the anode material without removing it from the housing. However, due to factors such as the strength of the crystal orientation, the technology for quantitatively acquiring the crystal information in the LIB anode material over a wide range had not been realized.

In collaboration with NISSAN ARC Ltd., the High Energy Accelerator Research Organization (KEK), and the Comprehensive Research Organization for Science and Society (CROSS), researchers in AIST successfully conducted nondestructive visualization of battery electrode degradation and quantification of the crystal phase types and densities. This was achieved by applying a newly developed analysis method to crystal structure imaging (Bragg-edge imaging) measurement by transmission spectrum analysis of neutron beams on new and degraded LIBs.

Neutron beams have high penetrating power and can penetrate the LIB housing to enable nondestructive observation of the interior. Furthermore, information on the crystal structure of the graphite or other anode material can also be obtained by analyzing the transmission spectrum of the neutron beam. This research group devised and applied a new analysis method that takes into account the crystal orientation of graphite to visualize the insertion/extraction state, density, and two-dimensional spatial distribution of lithium ions in graphite anodes, and to quantitatively clarify the difference between new and degraded LIB products. Utilization of this technology for nondestructive and operand observation of the LIB degradation process due to charging and discharging can be expected to contribute to the development of even higher performance batteries.