Advanced Semiconductor Materials Research

The objective of this research group is to advance the fundamental understanding of 2D systems, oxide catalysts, and functional interfaces by combining state-of-the-art global synchrotron experimentation with machine learning frameworks to accelerate material discovery, behavioral prediction, and performance optimization. We are committed to fostering research capacity in Bangladesh, nurturing the next generation of researchers through interdisciplinary and computational science, and delivering scalable technological solutions to the most pressing challenges in clean energy, environmental monitoring, and advanced electronics, thereby establishing leadership in materials and surface science research at home and abroad. With our commitment to interdisciplinary collaboration, international partnerships, and cutting-edge technological advancements, we strive to shape the future by creating sustainable and transformative surface-engineered solutions that benefit society as a whole.

INTEREST(S)

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VISION

The vision of this research group is to be at the forefront of surface science, nanomaterials, and nanotechnology research, development, and application. We aim to harness the potential of two-dimensional materials, model catalysts, and functional interfaces to provide cutting-edge solutions in a wide range of applications, including sustainable energy, environmental sensing, catalysis, and next-generation electronics.

MISSION

Our mission is to advance the fundamental understanding of advanced materials, including two-dimensional systems, oxide model catalysts, and functional interfaces, through active collaboration with leading global research institutions and access to state-of-the-art synchrotron facilities. We are integrating experimental data from our worldwide partners with machine learning (ML) techniques to accelerate data interpretation, predict material behavior, optimize catalytic and sensing performance, and discover novel surface configurations with unprecedented efficiency.

MEMBER(S)