Exploring defects in a solid-state electrolyte

Though solid-state batteries have caught the attention of the energy storage industry, their commercial application has so far been very limited, and there is a wealth of different potential materials to replace the liquid electrolytes used in today’s lithium-ion batteries in various stages along the path of scientific investigation and potential commercialization.

Scientists led by Cornell University in the U.S. took a closer look at one such material, enabled by the latest imaging techniques conducted at Argonne National Laboratory’s synchrotron light source facility, the Advanced Photon Source.

The group worked with a sample of aluminum-doped lithium lanthanum zirconium oxide (LLZO). Although oxide materials are thought to be more challenging than sulfides or polymers in terms of commercial production, oxides also have potential. And the Cornell researchers state that LLZO has shown promise with high ionic conductivity and good stability properties.

Crystal defects

After synthesizing a sample of LLZO, the group headed to the Advanced Photon Source where they employed a technique called Bragg Coherent Diffractive imaging, to shine an X-ray beam onto a one-micron sized grain of the material and create a 3D image of its inner structure. Full results of this experiment can be found in the paper X-ray Nanoimaging of Crystal Defects in Single Grains of Solid-State Electrolyte Li_7–3xAl_xLa₃Zr₂O_12, published in Nano Letters.

“These electrolytes were assumed to be perfect crystals,” said Cornell researcher Yifei Sun. “But what we find are defects such as dislocations and grain boundaries that haven’t been reported before.” The work further that process of doping the material with aluminum was responsible for many of these dislocations and boundary, and could inform the future development of solid-state batteries.

The group is now planning further research to understand how these defects affect the mechanisms at work in the battery as it charges and discharges, and also whether they can control the growth of these defects to gain a further advantage. “Now that we know exactly what we’re looking for, we want to find these defects and look at them as we operate the battery,” said the group’s senior scientist Andrej Singer. “We are still far away from it, but we may be at the beginning of a new development where we can design these defects on purpose to make better energy storage materials.”