Research

We design and study catalytic and magnetically guided nanomotors that convert chemical or electromagnetic energy into motion. These artificial microswimmers serve as model systems for non-equilibrium thermodynamics and information-to-energy conversion. Applications include targeted transport, sensing, and probing of quantum-biological effects in fluids.

Our group engineers strain-controlled thin films that self-roll, fold, or buckle into 3D microtubes and capsules. These structures reveal how elastic energy couples with electronic, photonic, and chemical properties at the nanoscale. The work bridges materials science and device fabrication, enabling flexible sensors and micromachines.

We investigate unresolved or contradictory results across physics, chemistry, and biology to uncover hidden variables or overlooked mechanisms. Each paradox becomes a seed for new experiments and theoretical models. By systematically decoding anomalies, NanoTRIZ opens fresh routes toward transformative discoveries.

We develop adaptive microfluidic platforms that mimic natural micro-environments for studying particle motion, reaction kinetics, and bio-synthetic interfaces. Custom chip designs integrate optical and magnetic control for real-time observation of energy and information flow. This technology underpins high-precision experiments for nanomotors, enzymes, and catalytic systems.

The NanoTRIZ AI Engine performs large-scale semantic mapping of scientific literature to identify unexplored intersections between disciplines. It analyzes trends, gaps, and emerging phenomena, generating hypotheses for novel experiments or devices. This system supports research planning and automatic knowledge discovery.

Our translational framework bridges idea generation and practical implementation through AI-assisted design, prototyping, and publication. We emphasize reproducibility, and ethical collaboration as the foundation for innovation. The outcome is a continuous pipeline from conceptual insight to tangible technological impact.