System Materials Processing Lab

We develop new rheological analysis methods to quantitatively describe complex viscoelastic behavior.

Our work focuses on extending classical rheological theory to propose novel evaluation approaches applicable to multiphase and nonlinear systems.

By integrating theoretical modeling with experimental validation, we aim to establish rheology as a predictive tool for materials design.

We design and evaluate polymer blends with tailored viscoelastic and biocompatible properties for biomedical use.

Current efforts include optimizing composition, crosslinking, and processability to achieve controlled mechanical and degradation behavior suitable for therapeutic and implantable materials. 

We investigate the internal structure and flow behavior of electrode slurries to improve processability and electrochemical performance.

By combining rheological and microscopic analysis, we develop quantitative approaches for characterizing dispersion, agglomeration, and network formation within complex slurry systems. 

Our research explores MXene-based slurry systems to understand their rheological characteristics and electrochemical functionality.

We analyze how MXene dispersion and interfacial interactions influence conductivity, viscoelasticity, and long-term stability. 

We study phase separation and interfacial dynamics in immiscible polymer blends.

Advanced rheological and electrochemical techniques are applied to reveal the evolution of morphology under flow and thermal conditions, establishing correlations between phase structure and macroscopic viscoelasticity.