Operando optical tracking of single-particle ion dynamics and phase transitions in battery electrodes

TL;DR

This paper introduces a simple optical microscopy technique to visualize and analyze lithium-ion dynamics and phase transitions in battery electrodes in real time, enabling high-throughput studies of battery materials.

Contribution

The authors develop a lab-based optical interferometric scattering microscope for nanoscopic imaging of ion dynamics, providing a new tool for battery research that does not rely on complex synchrotron methods.

Findings

Visualized lithium insertion/removal rates at single-particle level

Identified mechanisms of phase transitions during charge/discharge

Captured domain boundary formation related to lattice distortion

Abstract

Key to advancing lithium-ion battery technology, and in particular fast charging capabilities, is our ability to follow and understand the dynamic processes occurring in operating materials under realistic conditions, in real time, and on the nano- to meso-scale. Currently, operando imaging of lithium-ion dynamics requires sophisticated synchrotron X-ray or electron microscopy techniques, which do not lend themselves to high-throughput material screening. This limits rapid and rational materials improvements. Here we introduce a simple lab-based, optical interferometric scattering microscope to resolve nanoscopic lithium-ion dynamics in battery materials and apply it to follow the repeated cycling of the archetypical cathode material Li$_\textit{x}$CoO$_2$. The method allows us to visualise directly the insulator-metal, solid solution and lithium ordering phase transitions in this material. We determine rates of lithium insertion and removal at the single-particle level and identify different mechanisms that occur on charge vs. discharge. Finally, we capture the dynamic formation of domain boundaries between different crystal orientations associated with the monoclinic lattice distortion at around Li$_{0.5}$CoO$_2$. The high throughput nature of our methodology allows many particles to be sampled across the entire electrode and, moving forward, will enable exploration of the role of dislocations, morphologies and cycling rate on battery degradation. The generality of our imaging concept means that it can be applied to study any battery electrode, and more broadly, systems where the transport of ions is associated with electronic or structural changes, including nanoionic films, ionic conducting polymers, photocatalytic materials and memristors.