1. Ph.D.
2. M.Phil.
Main research areas of this group are solar energy (DSSC, perovskite solar cell, quantum dot solar cells), Li-ion battery, polymer electrolytes (gel & solid), electrode materials, nanomaterials (graphene, metal/metal oxides), computational chemistry, photocatalytic water splitting, transparent conducting oxide (TCO), molecular interaction in binary mixtures (solution Chemistry) etc.
The research work is conducted in collaboration with Department of Chemistry, University of Chittagong and other external national and international institutions (BCSIR, Bangladesh Atomic Energy Commission, University of Malaya, Malaysia, Sunway University, Malaysia etc.). Future collaboration/MoU will be signed with NUS, Singapore, Coppin State University, USA, University of Illinois Chicago, USA etc.
The modern characterization technique are used from various institutions such as BCSIR, Atomic Energy Commission, University Malaya, Sunway University, Coppin State University etc. All the modern facilities such as FTIR, XRD, SEM, EDX, 4PP, UV-Vis spectroscopy, TEM, HRTEM, DSC, TGA, BET, Electrochemical Work Station, Solar Simulator, IPCE, IMPS, IMVS will be managed to use for materials and device characterization.
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Metal-Organic framework (MOF):
Recently, our research group has made significant strides in the field of Metal-Organic Frameworks (MOFs), having successfully developed a MOF with remarkable properties. We are now focusing on optimizing the synthesis procedure of MOFs in our laboratory to make the process more efficient and scalable. Additionally, we are exploring the potential applications of MOFs in various fields, including heavy metal separation, photocatalytic dye degradation, microbial activity, battery electrodes, and more.
MOFs are a class of materials with a porous structure that exhibits high surface area, tunable pore size, and excellent thermal stability. Our research group has successfully synthesized a novel MOF using a combination of metal ions and organic ligands. This MOF shows great potential in several applications, including environmental remediation, energy storage, and catalysis.
One of the primary areas of focus for our research group is optimizing the synthesis procedure of MOFs in our laboratory. We believe that by doing so, we can create more opportunities for researchers to understand the synthesis process, characteristics, and applications of MOFs. We are continually exploring new methods and techniques to improve the synthesis process, which will ultimately lead to the creation of more efficient and scalable MOFs.
Furthermore, we are actively investigating the potential applications of MOFs in various fields. Our research is focused on heavy metal separation, photocatalytic dye degradation, microbial activity, and battery electrodes, among others. Our aim is to develop MOFs that can be used in practical applications and contribute to solving some of the most pressing issues facing society today.
Overall, our research group's success in developing MOFs with remarkable properties is a significant breakthrough in the field of materials science. By optimizing the synthesis procedure and exploring potential applications, we hope to create more opportunities for researchers to contribute to the advancement of MOFs and their use in practical applications.
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