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11. Materials for Energy and Environmental Sustainability: Materials that improve energy efficiency, enable clean energy generation, and reduce environmental impact—such as advanced batteries, catalysts, solar materials, and lightweight composites—are crucial for building a sustainable and low-carbon future.
12. Graphene Technology – 3D & 2D Materials and Carbon Nanotubes: Graphene and other 2D/3D advanced materials, along with carbon nanotubes, enable ultra-light, high-strength, and highly conductive structures, driving innovations in electronics, energy storage, composites, and next-generation nanotechnology.

13. Advanced Energy Materials: Advanced Energy Materials focuses on developing innovative materials—such as nanomaterials, solid-state electrolytes, perovskites, and energy-storage compounds—that enable next-generation batteries, solar cells, fuel cells, and other high-efficiency sustainable energy technologies.

14. Mechanics, Characterization Techniques and Equipment: This area focuses on understanding how materials behave under various forces, and uses advanced tools—like microscopy, spectroscopy, and mechanical testing equipment—to analyse their structure, properties, and performance at different scales.

15. Applications in Material Science Engineering: Materials Science and Engineering enables the development of advanced materials used in industries such as electronics, aerospace, automotive, energy, biomedical devices, and construction, improving performance, durability, and technological innovation.

16. Nano Materials & Nanocomposites: Nano Materials & Nanocomposites involve engineering materials at the nanoscale to achieve exceptional mechanical, electrical, thermal, and optical properties, with nanocomposites combining nanoparticles with bulk matrices to create highly advanced, multifunctional materials for cutting-edge applications

17. Emerging Smart Materials: Emerging smart materials are advanced materials that can sense and respond to external stimuli—such as temperature, pressure, light, or electric fields—by changing their properties in real time, enabling innovative applications in healthcare, robotics, electronics, and aerospace.

18. Semiconductors: Fundamentals to Emerging Applications: Semiconductors are materials with tunable electrical properties that form the backbone of modern electronics, enabling innovations from microchips and optoelectronics to advanced applications in AI hardware, quantum devices, power electronics, and next-generation communication technologies.

19. Advances in Nano Materials Science: Advances in Nano Materials Science focus on designing and manipulating materials at the nanoscale to achieve extraordinary mechanical, electrical, optical, and chemical properties, leading to breakthroughs in electronics, energy storage, biomedicine, and smart functional materials.

20. Biological & Chemical Sciences: These fields explore the fundamental processes of life and the chemical principles underlying them, combining biology and chemistry to understand living systems, develop new materials, medicines, and technologies, and solve real-world problems in health, environment, and industry.

21. Nano catalysis & Nano chemistry: Nano catalysis involves using nanoscale materials to accelerate chemical reactions with high efficiency, while nano chemistry focuses on designing and manipulating materials at the nanometer scale to achieve unique chemical, catalytic, and functional properties.