Before performing thermal analysis, first, determine the battery component of interest and its material identity. The component’s decomposition temperature, composition determination, oxidation, and solvent drying can be studied by thermogravimetric analysis (TGA).

Differential scanning calorimetry (DSC) can help to identify a material’s melting temperature, the heat of fusion, heat capacity, and glass transition. If the material melts at a high temperature (more than 1,200 °Celsius), a simultaneous DSC/TGA can analyze high-temperature melting and stability and determine composition.

When it comes to studying the stability of the material’s shape and size, a thermomechanical analyzer (TMA) can be used to analyze thermal expansion and shrinkage. The mechanical properties of the battery (deformation study) should be qualified by a dynamic mechanical analyzer (DMA) during manufacturing, which often requires working with slurries of solid particles, binders, and solvents.

Rheology provides critical insights into battery slurries at each manufacturing stage, including storage, mixing, coating, and drying. A rheological profile measurement can help ensure a uniform, defect-free coating that leads to the production of consistent, high-quality electrodes with high batch-to-batch repeatability and low scrap rates. Furthermore, the quantitative thermodynamic and kinetic behavior of electrolytes can be studied simply by using a thermal activity monitor (TAM) system, which is shown in the second case study.