Tag: energy storage systems

The liquid tech of self-healing batteries

The liquid tech of self-healing batteries

Materials scientists seek to develop better lithium (Li) metal batteries by improving structural stability and reducing dendrite formation that causes battery failure. It is well-known that instability at the metal electrode-electrolyte interface causes lithium dendrite growth, leading to short-circuiting and formation of inactive lithium. New electrolyte designs that control lithium deposition during cycling may solve these issues. Researchers are investigating liquid crystalline (LC) electrolytes under different conditions at MAX IV’s ForMAX beamline to determine whether these electrolytic materials are possible to align on demand. Successful results hold promise to propel the development of Li metal batteries as a next-generation power solution for electric vehicles and energy storage systems.

The study examines a foundational idea that the organised molecular structure and chemistry of LC electrolytes allow for ‘self-healing’ of the battery interfaces whereas conventional solvent-based liquid electrolytes fail. “LC electrolytes introduce an additional energy contribution for dendrite nucleation due to their strong anchoring energy and are therefore expected to supress the growth of dendrites from the electrode-electrolyte interface,” explained Owies Wani, study author and postdoctoral fellow at Aalto University. “Besides, due to their fluid nature, they can potentially flow into the crack formed in the interface upon cycling of the battery and thereby form a new healed interface.”  

The experimental phase included structural measurements of sample LC electrolytes with small- and wide-angle X-ray scattering (SWAXS) at ForMAX beamline to look at colloidal and molecular processes with applied stimuli of shear force at different temperatures. A rheometer supplies the force to align the material structure from a polydomain to a monodomain, which potentially creates straight, directed channels for efficient Li ion transport in the battery, thereby boosting ionic conductivity.

The group carried out three simultaneous measurements: rheology, SWAXS and polarized light imaging. “This was instrumental to understand the dynamic shear induced alignment in our LC electrolytes at different length scales,” explained Wani.

Read more on the MAX IV website

Image: From left) Bin Zhao, Xiaodan Hong, Mario Bello Piedrahita, Maximilian Hagemann, Owies Wani, Patrice Rannou and Zhongpeng Lyu.

Credit: Owies Wani

A promising step forward for the deployment of sodium-ion batteries

A promising step forward for the deployment of sodium-ion batteries

CNRS chemists synthesized and studied new compositions of materials for positive electrodes of sodium-ion batteries that constitute a sustainable alternative to lithium-ion batteries. These new electrodes have an increased energy density. A scientific advance recently published in the journal Nature Materials.

Faced with the growing demand for energy storage systems, high-performance lithium-ion batteries have become unbeatable on the market. However, their environmental impact and the uneven distribution of lithium resources raise questions. Their “cousins”, sodium-ion batteries, seem to be a promising alternative given the abundance and more homogeneous distribution of sodium. The various possible electrode materials are thus the subject of numerous studies to increase their performance, power and energy densities. In particular, NaSICON (sodium super ionic conductor) type materials composed of sodium, vanadium and phosphate are attracting keen interest as positive electrode materials because they have a particularly robust crystalline structure.

Read more on ALBA website