Rohit Yadav | High energy physics | Best Researcher Award

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Mr. Rohit Yadav | High energy physics | Best Researcher Award

National Institute of Technology Warangal | India

Rohit Yadav is a Research Scholar at the National Institute of Technology (NIT), Warangal, India, specializing in hybrid supercapacitors and electrode materials for energy storage systems. His research focuses on designing and developing high-performance, eco-friendly supercapacitors aimed at advancing electric vehicles (EVs) and promoting green energy solutions. Rohit’s work is essential for the sustainable energy revolution and has already contributed significantly to renewable energy storage and smart grid applications.

👨‍🎓Profile

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Early Academic Pursuits 🎓

Rohit completed his M.Sc. in Physics in 2020 from the Malviya National Institute of Technology, Jaipur, India. His dissertation focused on studying cathode materials for metal-air batteries, laying a strong foundation for his later work in advanced energy storage systems. His academic journey provided a deep understanding of material science and electrochemical processes, which continues to shape his innovative approach to supercapacitor research.

Professional Endeavors 🔬

As a Program Committee Member for the IEMDST 2024 Conference, Rohit played a crucial role in organizing and overseeing a global scientific event. Additionally, he served as the General Secretary of the Physics Society at NIT Warangal in 2023, organizing scientific talks and coordinating weekly research presentations. His leadership and collaboration in these roles underscore his commitment to fostering scientific dialogue and promoting academic growth in the scientific community.

Contributions and Research Focus 🔍

Rohit’s research interests span across the development of hybrid supercapacitors, focusing on the synthesis and characterization of novel electrode materials. His work directly impacts the advancement of energy storage systems for electric vehicles and renewable energy solutions. By enhancing the performance of supercapacitors with eco-friendly materials like mesoporous strontium titanate and activated carbon derived from natural biomass, he contributes to sustainable, efficient energy storage solutions. His dedication to green energy applications marks a crucial intersection of technology and environmental impact.

Research Skills 🛠️

Rohit is highly skilled in synthesis techniques such as sol-gel and hydrothermal methods for creating novel electrode materials. His expertise includes electrochemical characterization, materials optimization, and nanomaterial design, which are key in developing high-performance energy storage systems. Additionally, he is proficient in advanced analytical techniques, ensuring that his materials meet the rigorous demands of sustainable energy solutions.

Awards and Honors 🏆

Rohit’s dedication and hard work have been recognized through several accolades:

  • Best Paper Award – 2023: For his exceptional paper presented at an international conference.
  • Position Certificate in Mini Marathon – 2024: A testament to his balanced and disciplined approach to both academic and personal growth.

These honors highlight his outstanding contributions to the field of energy storage and his commitment to excellence in both academic and extracurricular endeavors.

Legacy and Future Contributions 🚀

Rohit’s long-term vision is to push the boundaries of hybrid supercapacitor technology and advanced electrode materials to further enhance energy storage systems for electric vehicles and renewable energy grids. His work is poised to play a crucial role in the global transition to sustainable energy solutions, and he aspires to continue contributing to green technologies that benefit both society and the environment.

Publications Top Notes

Synthesis and Electrochemical characterization of activated porous Carbon Derived from Walnut shells as an Electrode material for symmetric Supercapacitor Application

  • Authors: R Yadav, N Macherla, K Singh, K Kumari
    Journal: Engineering Proceedings 59 (1), 175
    Year: 2024

Structural-Morphological Insights into Optimization of Hydrothermally Synthesized MoSe2 Nanoflowers for Improving Supercapacitor Application

  • Authors: P Yadav, R Yadav, J Pani, RM Singh, D Singh, K Kusum, H Borkar, …
    Journal: Dalton Transactions
    Year: 2025

Temperature-dependent hydrothermal processing of WS2 nanorods with controlled growth morphology, crystallography and optical properties

  • Authors: DS Ahlawat, D Singh, R Yadav, K Kumari, H Borkar, J Gangwar
    Journal: Materials Letters 377, 137386
    Year: 2024

Electrochemical analysis of sol-gel and hydrothermal synthesized mesoporous strontium titanate spherical nanoparticles as electrode material for high-performance flexible supercapacitors

  • Authors: R Yadav, R Banoth, K Singh, H Borkar, K Kumari
    Journal: Materials Chemistry and Physics 328, 130004
    Year: 2024

Novel industrial biomass derived materials for super capacitor application in powering up electronic gadgets

  • Authors: P Yadav, PA Azeem, S Patel, G Mahar, R Yadav, H Borkar
    Journal: Journal of Energy Storage 97, 112653
    Year: 2024

 

 

Muneeb Ullah | High energy physics | Best Researcher Award

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Mr. Muneeb Ullah | High energy physics | Best Researcher Award

PhD, Pusan National University, Busan, South Korea

Muneeb Ullah, born on October 4, 1996, in Pakistan, is a highly motivated professional specializing in pharmaceutical sciences. Currently residing in Busan, South Korea, he is fluent in English, Urdu, and Pashto. Muneeb seeks a position in a result-oriented organization where his skills and education can contribute to mutual growth. His commitment to excellence is evident in his academic achievements and research contributions, positioning him as a valuable asset in the field of pharmacy.

Profile:

🎓Education:

Muneeb holds an MPhil in Pharmaceutical Sciences with a focus on Pharmaceutical Nanotechnology from the Department of Pharmacy, KUST, completed in 2022 with a first division score. Prior to that, he earned a BS in Pharmacy (Pharm-D) from KUST (2014-2019), also with first division honors. His academic journey includes a Pre-Medical F.Sc. from The Crescent Public School (2012-2013) and Matriculation from GHS Hurmaz (2010-2011), where he consistently achieved first division results.

Professional Experience:

Muneeb has diverse experience in education and research. As a Visiting Faculty Member at Billitong Higher Secondary School, he received the Best Teacher Award in 2020 for his impactful teaching. Additionally, he served as a Research Assistant at the National University of Medical Sciences (NUMS) in Islamabad, contributing significantly to various research initiatives. These roles have allowed him to blend his academic knowledge with practical applications, fostering a passion for teaching and research in the pharmaceutical field.

Research  Focus:

Muneeb’s research primarily focuses on pharmaceutical nanotechnology, highlighted by his MPhil thesis on developing Beclomethasone Dipropionate-loaded polymeric nanoparticles via a water-in-oil emulsion solvent evaporation method. His coursework includes pharmaceutics, nanotechnology, and biochemistry, providing a solid foundation for research methodologies. His laboratory skills encompass nanoparticle preparation, antimicrobial activity assessment, and bioinformatics analysis, equipping him to make significant contributions to the field of pharmaceutical sciences.

Awards and Honors:

Throughout his academic journey, Muneeb has received several prestigious awards. He was awarded the HEC-Indigenous Scholarship from 2016 to 2019 for his BS in Pharmacy at KUST. In May 2018, he received the Best Talent Award under the Prime Minister Laptop Scheme, recognizing his outstanding academic performance. Furthermore, he was honored with the Best Teacher Award for the 2020 session at Billitong Higher Secondary School, reflecting his dedication to education and student success.

📖 Publication Top Notes:

Title: Microbiome miracles and their pioneering advances and future frontiers in cardiovascular disease
  • Authors: Safdar, M., Ullah, M., Hamayun, S., Mustopa, A.Z., Hasan, N.
    Publication Year: 2024
    Citations: 1
Title: Development of Clindamycin-Releasing Polyvinyl Alcohol Hydrogel with Self-Healing Property for the Effective Treatment of Biofilm-Infected Wounds
  • Authors: Alifah, N., Palungan, J., Ardayanti, K., Yoo, J.-W., Hasan, N.
    Publication Year: 2024
    Citations: 0
Title: 3D printing technology and its revolutionary role in stent implementation in cardiovascular disease
  • Authors: Khan, M.A., Khan, N., Ullah, M., Naeem, M., Hasan, N.
    Publication Year: 2024
    Citations: 4
Title: Recent advancements in nanotechnology based drug delivery for the management of cardiovascular disease
  • Authors: Ullah, A., Ullah, M., Lim, S.I.
    Publication Year: 2024
    Citations: 7
Title: Nanotherapeutic approaches for transdermal drug delivery systems and their biomedical applications
  • Authors: Khan, S.U., Ullah, M., Saeed, S., Khan, M.A., Lu, K.
    Publication Year: 2024
    Citations: 4
Title: Single-cell RNA Sequencing (scRNA-seq): Advances and Challenges for Cardiovascular Diseases (CVDs)
  • Authors: Khan, S.U., Huang, Y., Ali, H., Ullah, M., Lu, K.
    Publication Year: 2024
    Citations: 7

 

Min Yang | High Energy physics | Best Researcher Award

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Prof. Min Yang | High Energy physics | Best Researcher Award

PHD at Qingdao University of Technology, Qingdao, China

Dr. Min Yang, based at Qingdao University of Technology, Qingdao, China, is a distinguished researcher recognized as a Highly Cited Researcher for Clarivate in 2022 and listed among the World’s Top 2% Scientists in 2023. With an H-index of 45, she has authored 83 influential papers, including 39 ESI HOT/Highly Cited papers, accumulating 8205 WOS citations. As the chief expert of the Qingdao Nanolubricant Quasi Dry Manufacturing Expert Workstation, her expertise spans grinding, precision machining, biomedical material processing, and the preparation of wearable sensors. Additionally, she has authored 4 books, contributing significantly to her field. High Energy physics

Professional Profiles:

Scopus

Researchgate

Education

phd, Qingdao University of Technology, Qingdao, China

Accolades

Min Yang is a Highly Cited Researcher for Clarivate in 2022 and recognized as one of the World’s Top 2% Scientists in 2023. She has made significant contributions, with 83 highly influential papers to her name, including 39 ESI HOT/Highly Cited papers. Her impressive H-index of 45 reflects the impact of her work, which has garnered a total of 8205 WOS citations. High Energy physics

Expertise

Her expertise extends to serving as the chief expert of the Qingdao Nanolubricant Quasi Dry Manufacturing Expert Workstation.

Publications

In addition to her prolific paper output, Min Yang has authored 4 books, 2 of which were published by Science Press.

Research Interest

Grinding and precision machining, Biomedical material processing, Preparation of wearable sensors

Research Focus:

Dr. Min Yang’s research focuses on various aspects of advanced manufacturing technology, particularly in the field of grinding and precision machining. Her recent work includes investigations into the grindability evaluation of ultrasonic-assisted grinding of silicon nitride ceramic using minimum quantity lubrication based SiO2 nanofluid. Additionally, she has contributed significantly to understanding material removal mechanisms and force modeling in ultrasonic vibration-assisted micro-grinding of biological bone. Dr. Yang’s expertise extends to exploring heat transfer mechanisms in cryogenic air minimum quantity lubrication grinding of titanium alloy and developing temperature field models in surface grinding. She continues to advance knowledge in these areas through her research at Qingdao University of Technology, Qingdao, China. High Energy physics

Publications

  1. Temperature field model in surface grinding: a comparative assessment, Publication: 2023.
  2. Material Removal Mechanism and Force Modeling in Ultrasonic Vibration-Assisted Micro-Grinding Biological Bone, Publication: 2023.
  3. Convective Heat Transfer Coefficient Model Under Nanofluid Minimum Quantity Lubrication Coupled with Cryogenic Air Grinding Ti–6Al–4VPublication: 2020.
  4. Nanobiolubricant grinding: a comprehensive reviewPublication: 2024.
  5. Kinematics and improved surface roughness model in milling, Publication: 2022.
  6. Graphene-based flexible wearable sensors: mechanisms, challenges, and future directions, Publication: 2023.
  7. Grindability Evaluation of Ultrasonic Assisted Grinding of Silicon Nitride Ceramic Using Minimum Quantity Lubrication Based SiO2 NanofluidPublication: 2024.
  8. Magnetic Bearing: Structure, Model and Control strategyPublication: 2023.
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