FUNCTIONAL AND LOW-DIMENSIONAL QUANTUM MATERIALS

We are developing smart materials that can store energy, convert it into electricity, and even help create eco-friendly technologies. These include materials that respond to electric and magnetic fields, ultra-thin layers with unique properties, and solutions for clean energy and safer nuclear systems

• Ferroelectric and Multiferroic Materials
• Low-dimensional ferroic and quantum materials, exotic polar states
• Materials for high-power energy storage and nuclear applications
• Energy conversion materials for actuation, environmental remediation, and green fuel generation

MODELING & AI-ENHANCED SIMULATIONS

We use advanced simulations and AI to understand how materials behave at the atomic level. We model complex processes, from energy reactions to electron structures, helping design smarter materials and technologies. Combining quantum physics and crystallography, these tools reveal hidden properties and guide innovation in energy, electronics, and science.

• Advanced and AI-based Simulations of Complex Materials
• Quantum modelling of elementary processes
• Quantum Crystallography

COMPLEX MATERIALS AND BIOPHYSICS

We design advanced materials for brain-like computing, energy-efficient devices, and pharmaceutical innovations. We study biomolecules to understand life’s processes and engineer molecular crystals for better medicines. By controlling defects and structure in complex materials, this research drives breakthroughs in health, electronics, and sustainable technologies.

• Materials for brain-inspired sensing and computing
• Physics of Biomolecules
• Molecules and Molecular Crystals of Pharmaceutical Interest
• Defect-engineering and structural organization in materials