Origin of anomalous high-rate Na-ion electrochemistry in layered bismuth telluride anodes

van der Waals layered metal chalcogenide Bi2Te3 has shown exceptional capacity and rate capability in alkali-ion batteries but the underlying reaction mechanism with Li+ , Na+ , and K+ remains undiscovered. It is unexpected that Na+ electrochemistry outperforms Li+ and K+ at high current densities. Here, in situ transmission electron microscopy is used to uncover nanoscale transformations during lithiation, sodiation, and potassiation, which follows two-step conversion and alloying reactions with Li+ and Na+, and three-step intercalation-conversion-alloying reactions with K. Counterintuitively, sodiation exhibits the highest reaction kinetics, and its origin can be elucidated by first-principles and finite-element simulations in two aspects. The lower interfacial strain accommodation energy between Bi2Te3 and its Na-conversion products allows more facile sodiation phase transformation than Li- and K-ion reactions. The higher electrochemo-mechanical stress concentration at the concave-shaped sodiation reaction front facilitates continued Na-ion diffusion and reaction propagation These fundamental insights are essential for fast-charging alkali-ion batteries.

Automated summary

In situ transmission electron microscopy was used to uncover nanoscale transformations during lithiation, sodiation, and potassiation of Bi2Te3 in alkali-ion batteries, with sodiation exhibiting the highest reaction kinetics. The origin of this phenomenon was elucidated through first-principles and finite-element simulations, pointing to lower interfacial strain accommodation energy and higher electrochemo-mechanical stress concentration as key factors. These insights are crucial for fast-charging alkali-ion batteries.