Nanomaterial and Nanotechnology
Nanomaterials and nanotechnology encompass the exciting and rapidly evolving field of manipulating matter at the nanoscale level. Nanotechnology is a multidisciplinary science and engineering discipline that focuses on the design, synthesis, characterization, and application of nanomaterials. It involves working with nanoscale structures, devices, and systems to create innovative solutions across a wide range of fields, including electronics, medicine, energy, environmental science, and advanced manufacturing. The field of nanomaterials and nanotechnology holds immense promise for revolutionizing diverse industries by enabling the development of advanced materials, high-performance electronics, targeted therapeutics, efficient energy systems, and sensitive sensors, among others. Researchers and scientists in this field strive to unlock the potential of nanotechnology to address pressing global challenges and improve our quality of life.INTEREST(S)
Electromagnetic Shielding Materials Characterization Techniques with Machine LearningSynthesis of Quantum Size NanomaterialsProperties of 2D Materials and NanotubesNanocomposites
VISION
Our vision is to be at the forefront of nanomaterials and nanotechnology research, development, and application. We strive to unlock the full potential of nanomaterials to enable groundbreaking solutions in diverse fields such as electronics, energy, medicine, environmental sustainability, and more. With our commitment to interdisciplinary collaboration and cutting-edge technological advancements, we aim to shape the future by creating sustainable and transformative nanotechnology solutions that benefit society as a whole.
MISSION
At AIUB, our mission in the domain of nanomaterials and nanotechnology is to advance scientific knowledge, drive innovation, and leverage the power of nanoscale materials and technologies to address pressing global challenges. Our objective is to explore and harness the novel properties of nanomaterials to revolutionize various industries and improve the quality of life for people around the world.
MEMBER(S)
Enhancement of dielectric properties and conduction mechanism in Sn doped BaTi-O3 system for energy storage application
The dielectric properties of this material are determined by the dielectric constant (𝜅′), which interpret the ability of the material to store electric energy in an electrical field. BaTiO3 is one of...
Biological synthesis of nanomaterials
IN PROGRESS