Avijit Ghosh | Solar cell | Best Faculty Award

Mr. Avijit Ghosh, Solar cell, Best Faculty Award

Research Assistant at Advanced Energy Materials and Solar Cell Research Laboratory, BRUR

Avijit Ghosh, an innovative electrical engineer, graduated with distinction (CGPA: 3.57/4.00) from Begum Rokeya University, Rangpur. Passionate about material science, solar cells, and density function theory, he served as a Research Assistant at the Advanced Energy Materials and Solar Cell Research Laboratory, BRUR, showcasing a two-year commitment to cutting-edge research. Avijit’s academic prowess earned him prestigious scholarships, including the Banghabondhu Brilliant Scholarship. Beyond academics, he held leadership roles, notably as the former Co-President of the Pabna District Student Welfare Association. Avijit is defined by his commitment to excellence, strong moral ethics, and a keen interest in advancing technological frontiers.

Professional Profiles:

Scopus profile

Orcid profile

Googlescholar profile

Researchgate profile

EDUCATION QUALIFICATION:📚

Degree: B.Sc. in Engineering Department/Group: Electrical and Electronic Engineering (EEE). University/Institute/School: Begum Rokeya University, Rangpur (BRUR) CGPA: 3.57/4.00

EXPERIENCE:

Position: Research Assistant Organization: Advanced Energy Materials and Solar Cell Research Laboratory, BRUR Period: 2022 – 2023 Duration: 2 Years.

ACHIEVEMENT AND AWARDS:

Banghabondhu Brilliant Scholarship: Awarded by Academic Council, BRUR for securing good results in exams for 3 consecutive semesters of B.Sc. study. Secondary School Merit Scholarship: Awarded by school for excellent performance in Secondary School Certificate Result. Junior School Merit Scholarship: Awarded by Rajshahi Education Board for getting ‘Talentpool Scholarship’ in Junior School Certificate Examination, 2012.

RESEARCH INTEREST:

Material Science, Solar Cell, Density Function Theory.

Research Focus:

Avijit Ghosh is a dedicated researcher with a primary focus on the exploration of novel inorganic halide perovskites and their properties. His research, spanning various publications in reputable journals, delves into the impact of strain, spin-orbit coupling, and biaxial strain on the structural, electronic, and optical characteristics of materials like Sr3AsI3, Sr3NCl3, and Sr3PI3. With a keen interest in enhancing solar cell efficiency, Ghosh has contributed to the field by investigating charge transport layers and novel materials like Sr3SbI3. His work extends to numerical simulations for performance enhancement, demonstrating a comprehensive approach to advancing materials science and renewable energy technologies.

Publications (TOP NOTES)

 

Investigation strain effects on the electronic, optical, and output performance of the novel inorganic halide perovskite Sr3SbI3 solar cell,  Publication date: 2024.

 

An in-depth analysis of how strain impacts the electronic, optical, and output performance of the Ca3NI3 novel inorganic halide perovskite, Publication date: 2024.

 

Unraveling the strain-induced and spin–orbit coupling effect of novel inorganic halide perovskites of Ca3AsI3 using DFT, Publication date: 2023.

 

The optical and electronic properties of inorganic halide perovskite Sr3NCl3 under applied biaxial strain, Publication date: 2023.

 

Inorganic novel cubic halide perovskite Sr3AsI3: Strain-activated electronic and optical properties, Publication date: 2023.

 

Exploring the impact of strain on the electronic and optical properties of inorganic novel cubic perovskite Sr3PI3, Publication date: 2023.

 

Investigating how the electronic and optical properties of a novel cubic inorganic halide perovskite, Sr 3NI 3 are affected by strain, Publication date: 2023.

 

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Yanhui Wang | High Energy Physics | Best Researcher Award

Prof. Yanhui Wang, High Energy Physics, Best Researcher Award

PHD at Yanshan University, Qinhuangdao, China

Dr. Yanhui Wang, a distinguished Professor at Hebei University of Engineering, specializes in advanced steel materials, focusing on bearing steel and rail steel. With a Ph.D. in Materials Science and Engineering from Yanshan University, his expertise extends to experimental design and computational simulation of materials. Throughout his academic journey, Dr. Wang has contributed significantly to understanding phase transformation, microstructure control, and deformation behavior. As a dedicated researcher, he actively shapes the field, emphasizing the practical applications of his work. Driven by a passion for material science, Dr. Wang continues to inspire through his teaching and cutting-edge contributions to the realm of advanced materials.

Professional Profiles:

Scopus profile

Researchgate profile

Academic Background:📚

Ph.D., School of Materials Science and Engineering, Yanshan University, Qinhuangdao, China, 2017. Master, School of Materials Science and Engineering, Yanshan University, Qinhuangdao, China, 2013. B.S., School of Materials Science and Engineering, Yanshan University, Qinhuangdao, China, 2011.

Professional Experience:

Professor, Hebei University of Engineering, December 2022 – Present. Associate Professor, Hebei University of Engineering, October 2017 – November 2022. Lecturer, Hebei University of Engineering, June 2017 – September 2017.

Research Focus:

Dr. Yanhui Wang’s research focuses on advanced steel materials, specifically bearing steel and rail steel. His expertise lies in experimental design and computational simulation of materials, with a particular emphasis on phase transformation, microstructure control, deformation behavior, and processing techniques. Driven by a passion for material science, he actively contributes to the field through innovative research and practical applications.

Publications (TOP NOTES)

Constructing composite active centers optimized with Cr-doped NiS/NiS2 heterostructure for efficiently catalyzing alkaline hydrogen evolution reaction,  Publication date: 2024.

Transition metal nitride/sulfide nanoparticles attached to nitrogen-doped carbon nanotubes synthesized by modified black powder detonation for efficient overall water splitting, Publication date: 2024.

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