Prashant Thakur | Experimental methods | Best Researcher Award

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Assist. Prof. Dr. Prashant Thakur | Experimental methods | Best Researcher Award

Assistant Professor at Career Point University, Hamirpur | India

Dr. Prashant Thakur is an Assistant Professor in the Department of Physics and the Nodal Officer at the Center for Green Energy Research (CGER) at Career Point University, Hamirpur, Himachal Pradesh, India. He is ranked among the Top 0.5% of Researchers Worldwide (2024) by ScholarGPS®, California, US. His expertise lies in Materials Physics, particularly in superparamagnetic lanthanide-doped Mn-Zn ferrite nanoparticles. He has published 22 research articles and holds a patent titled “Superparamagnetic Nanoparticles and Method for Preparation Thereof”. Dr. Thakur has actively contributed to the development of environmentally sustainable technologies in the fields of nanomaterials and green energy.

👨‍🎓Profile

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🎓Education

Dr. Thakur earned his Ph.D. in Materials Physics from Jaypee University of Information Technology, Solan in 2019. He also holds a B.Ed. in Teaching Science and Maths from HP University, Shimla (2014), an M.Sc. in Materials Physics from Shoolini University, Solan (2013), and a B.Sc. in Non-Medical from HP University, Shimla (2011). His education laid a strong foundation in physics and material sciences, preparing him for groundbreaking research in nanomaterials, magnetism, and energy solutions.

🏢Professional Experience

Dr. Thakur is currently serving as an Assistant Professor at Career Point University, Hamirpur. He previously worked as an Assistant Professor in the Department of Physics at Akal College of Basic Sciences, Eternal University (Feb 2019 – Feb 2021). He has also been a Teaching Assistant in the Department of Physics and Materials Science at Jaypee University of Information Technology, Solan, from Aug 2014 – Nov 2018. His academic roles have involved teaching materials physics and guiding research in nanomaterials, particularly superparamagnetic nanoparticles and magnetic ferrites.

🏆Awards and Honors

Dr. Thakur has been ranked among the Top 0.5% of Researchers Worldwide (2024) by ScholarGPS®, USA, a prestigious recognition. He has also received the Best Poster Presentation Award at a National Conference at Shoolini University (2013). Additionally, he has been honored as a Resource Person at the e-workshop on “Materials and their Characterization” at Maharaja Agrasen University, H.P. in 2021. Dr. Thakur’s work has earned him multiple accolades and has significantly contributed to the scientific community.

🧠Research Focus

Dr. Prashant Thakur’s research focuses on the synthesis and characterization of nanomaterials for applications in magnetic materials, environmental remediation, and energy storage. His key interests include superparamagnetic lanthanide-doped Mn-Zn ferrites and their potential in magnetic and electromagnetic applications. His work on bismuth-doped barium hexaferrites and green-synthesized nanoparticles for antimicrobial and photocatalytic applications demonstrates his dedication to sustainable technology. Dr. Thakur is also engaged in exploring green energy solutions to contribute to a cleaner environment.

🔬Research Skills

Dr. Thakur possesses a diverse set of research skills in nanomaterials synthesis, X-ray diffraction, magnetic characterization, and optical properties analysis. He is highly skilled in microwave sintering, sol-gel processes, and citrate sol-gel methods for the development of ferrites and nanoparticles. His expertise in structural and morphological analysis using tools like SEM, TEM, and XPS further enhances his ability to investigate the properties of advanced materials. He also possesses deep experience in electromagnetic shielding, photocatalysis, and environmental applications of nanomaterials, contributing significantly to sustainable material science.

Publications Top Notes

Efficient removal of toxic dyes from water using Mn3O4 nanoparticles: Synthesis, characterization, and adsorption mechanisms

  • Authors: Kamal Kishore, Jaswinder Kaur, Yasser B. Saddeek, Meenakshi Sharma, Manpreet Singh, Prashant Thakur, Dr. Yogesh Kumar Walia, Madan Lal, R. Suman, A.S. Reddy, et al.
    Journal: Journal of Molecular Structure
    Year: 2025

Green synthesized Fe‐doped ZnO NPs using aloe vera gel: Antimicrobial, structural, optical and magnetic properties

  • Authors: Shreya Chauhan, Prashant Thakur, Kamal Kishore, Madan Lal, Pankaj Sharma
    Journal: Journal of the American Ceramic Society
    Year: 2025

Optimized electromagnetic shielding properties using bismuth-doped barium hexaferrite nanoparticles

  • Authors: Neha Thakur, Indu Sharma, Prashant Thakur, Khalid Mujasam Batoo, Sagar E. Shirsath, Gagan Kumar
    Journal: Polyhedron
    Year: 2025

Enhanced photocatalytic and antimicrobial properties of nickel-doped barium M-type hexaferrites synthesized via citrate sol-gel method

  • Authors: Indu Sharma, Neha Thakur, Yasser A.M. Ismail, K.A. Aly, Pankaj Sharma, K.M. Batoo, Prashant Thakur
    Journal: Inorganic Chemistry Communications
    Year: 2024

Improved magneto-dielectric response and dielectric characteristics of rare earth doped Ba and Co based U-type hexaferrite

  • Authors: Indu Sharma, Sunil Sharma, Prashant Thakur, Sumit Bhardwaj, Munisha Mahajan, Shubhpreet Kaur, Gagan Anand, Rohit Jasrotia, A Dahshan, H.I. Elsaeedy, Pankaj Sharma, Gagan Kumar
    Journal: Materials Chemistry and Physics
    Year: 2024

Olfa Turki | Experimental methods | Best Researcher Award

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Assist. Prof. Dr. Olfa Turki | Experimental methods | Best Researcher Award

Faculty of Sciences , Tunisia

Olfa Turki is an accomplished Assistant Professor at FST with a deep expertise in Physics, particularly in materials science and piezoelectric nanocomposites. With a PhD in Physics and a Master’s in Condensed Matter Physics, Olfa has built a robust academic career. She has contributed extensively to the development of lead-free ceramics and nanocomposites for sensor technologies. Olfa is also an active participant in international research projects and has presented her findings at numerous conferences worldwide. Beyond academics, she is committed to societal development, having been a candidate in municipal elections in Sfax in 2022. Her research bridges the gap between theoretical studies and practical applications in energy storage and sensors.

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🎓Education 

Olfa Turki holds a PhD in Physics from 2017, focusing on materials science, specifically piezoelectric nanocomposites. She completed her Master’s Degree in Condensed Matter Physics in 2013, which provided her with a strong foundation in solid-state physics. Her academic journey began with a Bachelor’s Degree in Physics in 2011, where she gained the knowledge that underpins her later research. Olfa’s educational background is complemented by her Baccalaureate in Mathematics from 2008, which further sharpened her analytical and problem-solving skills. Throughout her studies, Olfa has demonstrated a passion for scientific inquiry and a commitment to advancing knowledge in materials physics. Her academic qualifications are paired with hands-on experience in various scientific programs like Origin and Fullprof, enhancing her ability to analyze and present research data effectively. Olfa’s education continues to shape her innovative approach to solving complex scientific problems.

🏢Professional Experience 

Olfa Turki has accumulated a wealth of experience in teaching and research. She currently serves as an Assistant Professor at the Faculty of Sciences of Tunis (FST), where she teaches physics and conducts cutting-edge research. Olfa has also held contractual assistant positions at various institutions, including the Institute of Physics and Engineering (IPEIS) and the Institute of Information and Communication Technologies (ISGI), from 2015 to 2023. In these roles, she gained extensive experience in curriculum development, lecturing, and mentoring students. Olfa’s practical involvement in research is equally impressive, with significant contributions to projects on sensor autonomy and nanocomposite development. She has worked on national and international projects, collaborating with leading scientists in the field. Olfa has presented her work at various prestigious scientific conferences, both orally and in posters, solidifying her position as a respected researcher in her field.

🏆Awards and Honors

Olfa Turki has been recognized for her outstanding contributions to the field of material science and physics. While no formal awards are mentioned, her significant achievements in research, publications, and conference participation place her in high regard within the scientific community. Her work on piezoelectric nanocomposites and their application in sensor technologies has garnered attention, as evidenced by her numerous publications in high-impact journals such as Applied Surface Science and Ceramics International. In addition, Olfa’s involvement in international research programs like the AUF Research Support Program further highlights her scientific stature. Olfa’s role in municipal elections demonstrates her recognition as a leader in both academia and community involvement. Her ability to balance these responsibilities while maintaining a high standard of academic and research excellence showcases her dedication, which is often celebrated by her peers and colleagues.

🌍Research Focus 

Olfa Turki’s research focuses primarily on the development of lead-free ceramics and piezoelectric nanocomposites. Her work aims to improve the dielectric, ferroelectric, and electrocaloric properties of these materials, making them ideal candidates for use in sensor technologies, energy storage, and nanogenerators. Olfa has conducted in-depth studies on the effects of doping and substitution of various elements, such as lanthanides, to enhance the functional properties of ferroelectric ceramics. Her research has a direct application in creating more sustainable and efficient materials, particularly in the realm of green technologies. Moreover, Olfa explores the structural properties and microstructure of nanocomposites, offering innovative approaches for material synthesis and processing. Her recent international collaboration, NAPES, explores the development of nanocomposites for pressure sensors and energy harvesting, positioning her research at the intersection of advanced material science and applied technologies.

🧠Research Skills

Olfa Turki possesses a strong set of research skills that complement her work in materials science. She is proficient in using scientific programs such as Origin and Fullprof, tools that allow her to analyze complex data and model materials’ behavior. Olfa’s expertise in synthesis techniques, particularly sol-gel hydrothermal synthesis, enables her to create high-performance materials like piezoelectric nanocomposites and lead-free ceramics. Her ability to analyze and interpret dielectric, ferroelectric, and piezoelectric properties is a cornerstone of her research. Olfa is also adept in presenting her findings through oral and poster presentations at conferences, enhancing her scientific communication skills. Furthermore, she collaborates well within interdisciplinary teams and takes an active role in mentoring students, promoting research development. Her work is continually evolving, supported by her ability to stay updated on the latest scientific advancements and her commitment to collaborative research across international platforms.

Publications Top Notes

Sol-gel hydrothermal synthesis of lead-free BT nanoparticles for enhanced dielectric properties in PVDF nanocomposites

  • Authors: O. Turki, A. Slimani, S. Boufid, L. Seveyrat, V. Perrin, R. Ben Hassen, H. Khemakhem
    Journal: Applied Surface Science
    Year: 2025

Electrical, ferroelectric and electro-caloric properties of lead-free Ba₀.₈₅Ca₀.₁₅Ti₀.₉₅(Nb₀.₅Yb₀.₅)₀.₀₅O₃ multifunctional ceramic

  • Authors: I. Zouari, A. Dahri, O. Turki, V. Perrin, L. Seveyrat, Z. Sassi, N. Abdelmoula, H. Khemakhem, W. Dimassi
    Journal: Ceramics International
    Year: 2024

The effect of Erbium on physical properties of the BaCaTi(NbYb)O multifunctional ceramic

  • Authors: I. Zouari, O. Turki, L. Seveyrat, Z. Sassi, N. Abdelmoula, H. Khemakhem
    Journal: Applied Physics A
    Year: 2023

Ferroelectric Properties and Electrocaloric Effect in Dy₂O₃ Substitution on Lead‑Free NBT-6BT Ceramic

  • Authors: O. Turki, A. Slimani, I. Zouari, L. Seveyrat, Z. Sassi, H. Khemakhem
    Journal: Journal of Electronic Materials
    Year: 2022

Improved dielectric, ferroelectric, and electrocaloric properties by Yttrium substitution in NBT-6BT based ceramics

  • Authors: O. Turki, F. Benabdallah, L. Seveyrat, Z. Sassi, V. Perrin, H. Khemakhem
    Journal: Applied Physics A
    Year: 2022

 

 

 

Rajeshree Shinde | Experimental methods | Best Researcher Award

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Dr. Rajeshree Shinde | Experimental methods | Best Researcher Award

Sir Vithaldas Thackersey College of Home Science (Empowered Autonomous Status) | India

Dr. Rajeshree Amit Shinde is an Assistant Professor at Sir Vithaldas Thackersey College of Home Science, SNDTWU, Mumbai, with extensive experience in the field of chemistry and education. She has been actively involved in both teaching and administrative responsibilities at various academic levels since 2008. Dr. Shinde is deeply engaged in curriculum development, academic policy, and research. Additionally, she is a coordinator for several committees and has contributed significantly to the quality assurance process at her institution. She is passionate about interdisciplinary learning and has made notable contributions to the integration of science with real-world applications. Dr. Shinde’s research interests span drug-PNP interactions, protein stability, and physicochemical properties of osmolytes.

👨‍🎓Profile

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🎓Education

Dr. Shinde earned her Ph.D. in Chemistry from the Indian Institute of Technology (IIT) Bombay (2013-2018) under the supervision of Prof. Nand Kishore, focusing on the physicochemical properties of amino acids. She completed her M.Sc. in Chemistry at IIT Bombay (2006-2008), where she demonstrated exceptional academic aptitude with a 7.91 CPI. She also earned her B.Sc. in Chemistry from KET’s V.G. Vaze College, Mumbai, graduating with an impressive 84%. Dr. Shinde has always excelled in her academic journey, from HSC to S.S.C, receiving commendable marks. She has shown significant commitment to continuous professional development through various workshops, training programs, and certifications, including MOOCs and FDPs on topics related to science and education.

🏢Professional Experience

Dr. Shinde has over 15 years of experience in the academic field. Currently, she serves as an Assistant Professor at Sir Vithaldas Thackersey College of Home Science, SNDT Women’s University, since 2010. Prior to this, she was an Assistant Professor at KET’s V.G. Vaze College, Mumbai, from 2008-2009. Throughout her career, Dr. Shinde has undertaken several academic responsibilities, including being a member of the Academic Council, UG Ad-hoc Board of Studies, and a special invitee for the Board of Studies for the Food, Nutrition, and Dietetics Department at her current institution. She has also been involved in the design and development of innovative syllabi for diverse courses. Dr. Shinde has been instrumental in guiding M.Sc. students, shaping the next generation of researchers, and playing a pivotal role in institutional governance.

🏆Awards and Honors

Dr. Shinde’s career is distinguished by several accolades. In 2018, she was the winner of the cartoon competition during Vigilance Awareness Week at IIT Bombay. She has also contributed to national and international journals, with several publications in high-impact research areas such as physicochemical properties of amino acids and quantum dots as antimicrobial agents. Dr. Shinde has actively participated in conferences, workshops, and seminars, presenting her research findings in multiple oral and poster presentations, including those at the Mega Conclave Mission Millets in 2023. Her leadership was recognized in organizing multiple events, including the YUVA Mahotsav and regional seminars. She has also served as an examiner for Ph.D. theses, further cementing her role in the academic community.

📚Research Focus

Dr. Rajeshree Shinde’s research primarily explores drug-PNP interactions, the physicochemical properties of osmolytes, and their impact on protein stability. Her Ph.D. thesis focused on the synergistic effects of amino acids on protein stability, which provides insights into the behavior of osmolytes and biomolecules in various solutions. Dr. Shinde’s expertise includes utilizing advanced instrumental techniques such as UV-VIS spectrophotometry, fluorescence spectrophotometry, and isothermal titration calorimetry. Additionally, her ongoing projects investigate the nutritional efficacy of millets and moringa leaves powder as food fortificants. Dr. Shinde’s interdisciplinary approach combines chemistry with nutrition, making her work relevant to the development of functional foods and dietary interventions. She is actively engaged in research collaborations and has secured research grants for projects on energy bars and protein nanoparticle applications.

🧠Research Skills 

Dr. Rajeshree Amit Shinde is proficient in a range of instrumental techniques that support her research in chemistry and food science. Her expertise includes UV-VIS Spectrophotometry, Fluorescence Spectrophotometry, Isothermal Titration Calorimetry, Circular Dichroism, and High-Performance Liquid Chromatography (HPLC), among others. She has also conducted extensive work with Infrared Spectroscopy to analyze molecular structures and interactions. These techniques enable her to probe the thermodynamic and conformational behavior of proteins in the presence of osmolytes, which is central to her research. Dr. Shinde is skilled in data analysis, utilizing tools like Google Sheets for compiling research data, particularly in the context of AQAR submissions and research publications. Her research not only emphasizes chemical analysis but also integrates interdisciplinary approaches, combining food science, biochemistry, and sustainability, to develop functional food solutions with practical applications.

 

Ramesh Sharma | Experimental methods | Best Researcher Award

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Dr. Ramesh Sharma | Experimental methods | Best Researcher Award

DRDO | India

Dr. Ramesh Chand Sharma is a highly respected Group Director & Outstanding Scientist at DRDO (Defence Research and Development Organisation), with a vast array of experience in Laser Physics, Spectroscopy, LiDAR Technologies, and Bio-Photonics. His expertise spans over 25 years of pioneering work in research, development, and technology transfer. He has served in key leadership roles across international institutions and governmental organizations, contributing significantly to national security, environmental science, and defense technologies.

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📚 Early Academic Pursuits

Dr. Sharma’s academic journey started with a Bachelor’s degree in Physics from the University of Garhwal, Srinagar (1989). He continued his education by completing a Master’s degree (1991) in Physics with a specialization in Electronics from the University of Garhwal, and later pursued his Ph.D. in Laser Physics from Banaras Hindu University and IIT Kanpur (1995). His academic foundation laid the groundwork for his future innovative contributions in Laser Spectroscopy and Advanced Technology Development.

💼 Professional Endeavors

Dr. Sharma’s career has been marked by his international exposure and leadership in R&D roles. He has held prestigious positions at world-renowned institutions such as IIT Kanpur, University of California, NASA, and Academia Sinica (Taipei, Taiwan). Over the years, he has advanced to top roles in DRDO, including Project Director, Technical Director, and Group Director. His leadership extends beyond national boundaries, having led significant international collaborations in laser technologies, LiDAR systems, and bio-agent detection technologies.

🧑‍🔬 Contributions and Research Focus

Dr. Sharma’s research spans several cutting-edge fields, with a primary focus on Laser Physics, LiDAR, Spectroscopy, and Bio-Photonics. His pioneering work in Laser DEW (Directed Energy Weapons), LiDAR sensing, and explosive detection has led to breakthroughs in defense technologies and environmental monitoring. He has also contributed to the development of photoacoustic sensors, which have been demonstrated for bio-agent detection from 1 km standoff distance.

🌍 Impact and Influence

Dr. Sharma’s work has had a far-reaching impact, especially in the fields of national security, defense, and environmental protection. His role in developing LiDAR technologies for the detection of chemical and biological warfare agents has been crucial for India’s defense preparedness. His technologies have been transferred to industries, and they are now being used for hazardous material detection, explosive detection, and bio-threat identification. Through his research and innovation, Dr. Sharma continues to influence the scientific community, government agencies, and industry leaders.

📰 Academic Citations

Dr. Sharma’s academic works have been widely cited across the globe, with publications in renowned journals such as Optics Letters, Spectroscopy Letters, and J Laser Optics and Photonics. Notable works include papers on multi-anode PMT Bio-LiDAR systems, quantum laser sensors for defense, and ultra-sensitive detectors for explosive chemicals. His works are regularly cited for their significant advancements in laser-based sensing, detection technologies, and bio-safety applications.

🧑‍🏫 Research Skills

Dr. Sharma is a leader in experimental physics and applied research. His expertise spans laser technology, nonlinear optics, chemical dynamics, and biosensors. He is proficient in laser spectroscopy, THz spectroscopy, and LiDAR systems, and he is instrumental in the development and integration of complex systems. His role in product development and technology transfer showcases his skill in bridging the gap between cutting-edge research and practical, deployable solutions.

🎓 Teaching Experience

Dr. Sharma’s contributions extend to mentoring the next generation of scientists and engineers. He has served as the course director for continuing education programs (CEP) on Lasers, Spectroscopy, and LiDAR for defense applications. As a lecturer and trainer, he has played a pivotal role in developing curricula and workshops that bridge theory with practical applications for emerging technologies in defense and industrial sectors.

🏆 Awards and Honors

Dr. Sharma’s contributions to science and technology have been widely recognized through various prestigious awards:

  • Technology Award (LiDAR for Chemical & Biological Agent Detection) by DRDO (2011).
  • Commendation Certificate for Laser Photoacoustic Sensor Technology for explosive detection (2012).
  • Science Day Lecturer Oration Award (2019).
  • Indian Scientist Award, selected for Best Researcher Award (2022).

These accolades reflect his outstanding achievements and continued excellence in research and technology development.

🏅 Legacy and Future Contributions:

Dr. Sharma’s career is marked by groundbreaking achievements and continued contributions to science and technology. His innovative work in laser-based sensing technologies has already made an impact on national defense and environmental protection. Looking ahead, he aims to expand into quantum technologies, AI-enabled sensing systems, and advanced bio-threat detection systems. As he continues his work at FACET, DRDO, his legacy of scientific leadership and technological innovation will no doubt inspire future generations of researchers.

Publications Top Notes

Temporal evolution of opto-galvanic effect in normal glow discharge of argon

  • Authors: Sharma, R.C., Das, B.K., Sharma, G., Saraswat, V.K., Thakur, S.N.
    Journal: Spectroscopy Letters
    Year: 2024

Early detection and warning of standoff bio-threats using ultraviolet laser wavelengths

  • Authors: Kumar, S., Vats, R., Parmar, A., Das, B.K., Sharma, R.C.
    Journal: Journal of Laser Applications
    Year: 2023

Photomechanical detection of bioaerosol fluorescence free-from solar background

  • Authors: Sharma, R.C., Kumar, S., Parmar, A., Singh, K.P., Thakur, S.N.
    Journal: Optics and Laser Technology
    Year: 2022

Remote mid IR Photoacoustic Spectroscopy for the detection of explosive materials

  • Authors: Mann, M., Rao, A.S., Sharma, R.C.
    Journal: Chemical Physics Letters
    Year: 2021

Standoff pump-probe photothermal detection of hazardous chemicals

  • Authors: Sharma, R.C., Kumar, S., Parmar, A., Prakash, S., Thakur, S.N.
    Journal: Scientific Reports
    Year: 2020

 

 

 

Thiyagarajan M | Experimental methods | Best Researcher Award

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Dr. Thiyagarajan M | Experimental methods | Best Researcher Award

JNN Institute of Engineering | India

Dr. Thiyagarajan M. is an accomplished physicist with a strong foundation in material synthesis and crystal growth. He holds a Ph.D. in Physics from Vellore Institute of Technology (VIT) and has been recognized as a Research Supervisor by Anna University. His academic journey and professional career reflect his deep commitment to research and education, focusing on nonlinear optical applications and the development of advanced materials. He is currently an Assistant Professor in the Department of Physics at JNN Institute of Engineering, Chennai.

👨‍🎓Profile

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Early Academic Pursuits 🎓

Dr. Thiyagarajan’s academic journey began with a Bachelor of Science (B.Sc.) in Physics from Sri Vidya Mandir Arts & Science College (2011), where he excelled with a 76.2%. His passion for physics led him to pursue a Master of Science (M.Sc.) in Physics from Periyar University, achieving a 70.7%. His academic brilliance culminated in a Ph.D. in Physics, awarded by VIT-Chennai in July 2024, under the guidance of Dr. G. Vinitha.

Professional Endeavors 💼

Dr. Thiyagarajan’s professional career reflects a balance between teaching and research. He is dedicated to fostering a progressive and competitive work culture in academia. As an Assistant Professor at JNN Institute of Engineering since September 2024, he strives to bring innovative approaches to teaching physics while guiding students in research projects. His efforts have earned him recognition for his outstanding communication skills and his ability to inspire students to reach their academic potential.

Contributions and Research Focus 🔬

Dr. Thiyagarajan’s primary research focus is on the synthesis, growth, and characterization of novel materials, particularly those with applications in optoelectronics and nonlinear optics (NLO). His research on morpholinium-based crystals has paved the way for significant contributions to material science. He utilizes low-temperature solution growth techniques and the SR method to create organic-based single crystals with enhanced thermal, mechanical, and optical properties. These contributions are critical for advancing technologies in electronic devices, laser applications, and advanced sensors.

Research Skills 🧪

Dr. Thiyagarajan possesses a broad spectrum of research skills, including expertise in X-ray diffraction (XRD), thermogravimetric analysis (TGA), UV-Vis-NIR spectroscopy, and chemical etching. His work with high-purity chemicals, along with his proficiency in laser damage threshold and Z-scan measurements, has enabled him to make cutting-edge contributions in the field of material characterization. His expertise in low-temperature crystal growth and crystal cutting/polishing is instrumental in creating materials with exceptional properties.

Teaching Experience 👨‍🏫

As an Assistant Professor at JNN Institute of Engineering, Dr. Thiyagarajan brings a wealth of teaching experience to the classroom. His passion for teaching physics drives him to use innovative methodologies that encourage active learning and critical thinking. He is known for his ability to simplify complex concepts and make them accessible to students at all levels. His commitment to student development extends beyond the classroom, as he actively mentors students in research projects and guides them through academic challenges.

Awards and Honors 🏆

Dr. Thiyagarajan’s research and teaching excellence have been recognized with several awards and honors:

  • Best Poster Presentation Award at the 21st National Seminar on Crystal Growth and Application (2018)
  • Life Membership in the Indian Association for Crystal Growth (Membership No. 029/2012)
  • Recognition as a Research Supervisor by Anna University
  • Completion of the NPTEL Online Course on Structural Analysis of Nanomaterials with an Elite Grade in August 2024

Legacy and Future Contributions 🔮

Dr. Thiyagarajan is poised to continue making substantial contributions to material science and optoelectronics in the years to come. His innovative work in crystal engineering and nonlinear optical materials lays the foundation for future developments in next-generation optoelectronic devices. With his continuous commitment to research, Dr. Thiyagarajan aims to push the boundaries of material science and contribute to the global scientific community. As his research continues to evolve, his legacy will undoubtedly inspire future generations of scientists and engineers.

Publications Top Notes

Simulation analysis on furnace pressure for reducing the impurities concentrations distribution during the growth of mc-Si ingot by DS process: Solar cell applications

  • Authors: Sekar, S., Maadhu, T., Gurusamy, A., Gandhiraj, V., Perumalsamy, R.
    Journal: Chemical Physics
    Year: 2024

Novel Metal-Organic Framework and Crystal Engineering of Bismorpholinium Mercury(II) Tribromo Chloride (BMMC) for Optoelectronic Applications

  • Authors: Maadhu, T., Jauhar, R.M., Raja, A., Gandhiraj, V., Senthil Pandian, M.
    Journal: Crystal Growth and Design
    Year: 2024, 24(4), pp. 1632–1647

Enhancement of optical, electrical, mechanical and thermal properties with Hirshfeld surface analysis of organic piperazine para-nitrophenol crystals: An effective material for NLO device fabrication

  • Authors: Kannan, V., Maadhu, T., Periyasamy, P., Gandhiraj, V., Periyasamy, P.
    Journal: Journal of Solid State Chemistry
    Year: 2024, 330, 124457

Synthesis, experimental and theoretical studies of morpholinium bromide single crystal for NLO application

  • Authors: Maadhu, T., Jauhar, R.O.M., Raja, A., Pandian, M.S., Periyasamy, P.
    Journal: Journal of Molecular Structure
    Year: 2023, 1294, 136522

Design, crystal growth and characterizations of novel bis morpholinium zinc bromide single crystals for optoelectronic applications

  • Authors: Maadhu, T., Gandhiraj, V.
    Journal: Optical Materials
    Year: 2023, 138, 113694

Growth, structural, optical, thermal and mechanical properties of morpholinium 3,5-Dinitrosalicylate single crystals for nonlinear optical applications

  • Authors: Maadhu, T., Vinitha, G.
    Journal: Journal of Materials Science: Materials in Electronics
    Year: 2022, 33(26), pp. 20911–20928

 

 

 

John Goff | Experimental methods | Best Researcher Award

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Prof. John Goff | Experimental methods | Best Researcher Award

University of Lynchburg | United States

John Eric Goff is a Professor of Physics at the University of Lynchburg, with extensive experience in the field of sports engineering, fluid dynamics, and computational physics. Over the course of his career, he has made significant contributions to the study of aerodynamics in sports, the physics of surfaces, and optics. His academic journey began at Vanderbilt University, where he earned his B.S. in Physics and Mathematics in 1992, followed by an M.S. in Physics and Ph.D. in Physics from Indiana University. His thesis on the photon-drag effect in simple metals set the stage for his further academic pursuits and professional contributions.

👨‍🎓 Profile

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Early Academic Pursuits 🎓

Dr. Goff’s academic path began with a passion for physics and mathematics, which led him to Vanderbilt University for his undergraduate studies. From there, he continued his education at Indiana University, where he completed both his Master’s and Ph.D. His dissertation work focused on the photon-drag effect in simple metals, a topic that would shape much of his future research endeavors. His early academic experiences, including roles as an Associate Instructor and a Physics Instructor, honed his teaching abilities and deepened his understanding of the complexities of condensed matter physics.

Professional Endeavors 🌍

Dr. Goff has held notable academic positions at institutions such as Lynchburg College (now University of Lynchburg), where he served as Chair of the Department of Physics and Professor of Physics. His roles also include a Visiting Professorship at the University of Sheffield (UK), allowing him to engage with an international community of scientists and engineers. His research endeavors have spanned several interdisciplinary fields, including sports physics, fluid dynamics, and computational simulations of physical systems. His experience teaching and researching in these diverse areas has made him a prominent figure in the academic and sports engineering communities.

Contributions and Research Focus 🔬

Dr. Goff is best known for his work in the physics of sports, where he investigates the aerodynamics of soccer balls, the physics of cycling, and the design of sports equipment like climbing helmets. His research has led to numerous articles in prestigious journals, including studies on soccer ball aerodynamics and Tour de France modeling. Dr. Goff’s research has practical applications in both engineering and sports performance, and he continues to explore new avenues in fluid dynamics, sports engineering, and numerical simulations. He is also dedicated to mentoring students, helping them bridge the gap between theory and practical application in physics.

Impact and Influence 🌟

Dr. Goff’s work has had a profound impact on both the academic community and the sports industry. His research on soccer ball flight trajectories, cycling performance modeling, and sports equipment design has influenced the way engineers design and test sports equipment. His contributions to sports engineering education and his advocacy for using numerical modeling in the classroom have reshaped how students approach problem-solving in physics. Through his research articles, teaching, and collaborations, Dr. Goff has established himself as a key figure in the application of physics to real-world sports challenges.

Academic Cites 📚

Dr. Goff’s work is widely cited in the academic community, with contributions to journals such as the American Journal of Physics, Journal of Sports Engineering and Technology, and European Journal of Physics. His publications on soccer ball aerodynamics, Tour de France modeling, and sports engineering are often referenced by researchers in the field. His citation record attests to his influence in applied physics, particularly in the study of fluid dynamics and sports biomechanics.

Research Skills 🔧

Dr. Goff possesses a broad set of research skills that include expertise in numerical simulations, fluid dynamics modeling, and computational physics. He is fluent in programming languages such as FORTRAN and Mathematica, as well as Linux systems, making him well-equipped to tackle complex physical simulations. His ability to collaborate across disciplines, combining theoretical insights with practical engineering solutions, has resulted in innovative studies that bridge the gap between physics and sports technology.

Teaching Experience 📖

With over two decades of teaching experience, Dr. Goff has taught a wide variety of courses at both the undergraduate and graduate levels. His courses span topics from classical mechanics and electromagnetic theory to quantum mechanics and computational physics. He has also developed general education courses like Physics of Sports, helping non-science majors engage with physics in a way that connects to their everyday lives. Dr. Goff is known for his student-centered teaching style, using interactive techniques and real-world examples to foster a deep understanding of complex concepts.

Awards and Honors 🏆

Dr. Goff’s contributions to teaching, research, and student mentoring have been recognized with numerous awards, including the James A. Huston Award for Excellence in Scholarship and the Faculty Award for Excellence in Research Mentoring at the University of Lynchburg. He has also been honored with the Sigma Nu Herbert Bruce Award for being an outstanding faculty member, and multiple Frank R. Haig Prizes for best papers from four-year colleges at the American Association of Physics Teachers meetings. These accolades reflect Dr. Goff’s excellence in both academic scholarship and mentorship.

Legacy and Future Contributions 🔮

Dr. Goff’s legacy lies in his innovative teaching methods and his impactful research at the intersection of physics and sports engineering. His continued research will likely focus on improving sports performance modeling and engineering design. Through his research projects with students, his mentorship will shape the next generation of physicists, engineers, and sports scientists. Dr. Goff’s future contributions will undoubtedly advance our understanding of fluid dynamics and its applications to sports technologies, influencing both academic and practical fields for years to come.

  Publications Top Notes

The Aerodynamics of New Design Soccer Balls Using a Three-Dimensional Printer

  • Authors: Sungchan Hong, John Eric Goff, Takeshi Asai
    Journal: Applied Sciences
    Year: 2024

Aerodynamic comparisons between Al Rihla and recent World Cup soccer balls

  • Authors: John Eric Goff, Sungchan Hong, Takeshi Asai
    Journal: Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology
    Year: 2022

Multiple approaches to incorporating scattering states in non-degenerate perturbation theory

  • Authors: John Goff
    Journal: American Journal of Physics
    Year: 2020

Influence of Surface Properties on Soccer Ball Trajectories

  • Authors: John Goff
    Journal: Proceedings
    Year: 2020

Measurements of the Flight Trajectory of a Spinning Soccer Ball and the Magnus Force Acting on It

  • Authors: John Goff
    Journal: Proceedings
    Year: 2020

 

Hosameldeen Elshekh | Experimental methods | Best Researcher Award

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Dr. Hosameldeen Elshekh | Experimental methods | Best Researcher Award

Dr. Hosameldeen Elshekh | Southwest jiaotong University | China

👨‍🎓 Profile

🎓 Early Academic Pursuits

Dr. Hosameldeen Elhadi Abdelrhman Elshekh began his academic journey with a B.Ed. (Honors) in Physics and Mathematics from the University of Gezira, Sudan, in 2009. His exceptional performance and passion for physics and materials science paved the way for his higher education. He earned an M.Sc. in Physics from the same institution in 2016, followed by an M.Sc. Qualifying in Physics from the University of Khartoum in 2013. Currently, he is pursuing a Ph.D. in Physics at Southwest Jiaotong University, China, where he has been conducting advanced research since 2018.

🏫 Professional Endeavors

Dr. Hosameldeen’s professional journey commenced as a University Teaching Assistant at the University of Gezira, Sudan (2011–2014). He later progressed to a Physics Lecturer role (2016–2018), where he developed undergraduate physics courses and mentored students. His focus on curriculum innovation and science outreach programs highlights his dedication to fostering education and promoting science in the community.

🔬 Contributions and Research Focus

With expertise in material science, nanomaterials, and memristive devices, Hosameldeen specializes in thin films and their electrical and magnetic properties. His research integrates theoretical and experimental physics, focusing on memristors, resistive switching memory, and nanostructured materials. His work includes advanced synthesis techniques like electrochemical oxidation and magnetron sputtering, along with material characterization using SEM, EDS, and XRD.

🌍 Impact and Influence

Dr. Hosameldeen has co-authored nine SCI-indexed publications, contributing to advancements in resistive switching memory and bioelectronic devices. His collaborative research with peers worldwide reflects his commitment to fostering interdisciplinary partnerships. His work on TiOx-based memristors and MoSe2 nanosphere arrays demonstrates the potential of his innovations in sustainable technologies and electronics.

📚 Academic Citations

Dr. Hosameldeen’s contributions are recognized globally, with his publications indexed in Web of Science, Google Scholar, and ResearchGate. His research on WOx/TiOy heterojunctions and Zn-Al nanosheets-based memristors has been widely cited, underscoring his influence in the field of materials physics.

🛠️ Technical Skills

Hosameldeen excels in synthesis and characterization of nanomaterials, with hands-on expertise in tools like SEM, EDS, XRD, and advanced techniques like electrochemical oxidation. His skills in developing and testing memristive devices and thin-film materials are complemented by his ability to design and implement laboratory modules for educational purposes.

👨‍🏫 Teaching Experience

With over eight years of teaching experience, Hosameldeen has demonstrated excellence in curriculum development, student mentoring, and laboratory instruction. At the University of Gezira, he played a pivotal role in modernizing the physics curriculum and conducting research workshops. His dedication to science outreach programs showcases his passion for empowering students and local communities through education.

🌟 Legacy and Future Contributions

Dr. Hosameldeen’s research is shaping the future of nanotechnology and electronic devices, offering innovative solutions to scientific challenges. His commitment to advancing materials science and mentoring the next generation of scientists cements his legacy as an influential educator and researcher. Looking ahead, he aims to expand his contributions to global scientific collaboration and continue his exploration of sustainable material technologies.

Top Noted Publications

Nonvolatile behavior of resistive switching memory in Ag/WOx/TiOy/ITO device based on WOx/TiOy heterojunction
  • Authors: Hosameldeen Elshekh, Hongyan Wang, Chuan Yang, Shouhui Zhu
    Journal: Journal of Applied Physics
    Year: 2024
Nonvolatile resistive switching memory behavior of the TiOx-based memristor
  • Authors: Hosameldeen Elshekh, Hongyan Wang, Shouhui Zhu, Chuan Yang, Jiangqiu Wang
    Journal: Chemical Physics
    Year: 2024
An excellent resistive switching memory behaviour based on assembled MoSe2 nanosphere arrays
  • Authors: Mao Shuangsuo, Hosameldeen Elshekh, Mayameen S. Kadhim, Yudong Xia, Guoqiang Fu, Wentao Hou, Yong Zhao, Bai Sun
    Journal: Journal of Solid State Chemistry
    Year: 2019
Effect of crystalline state on conductive filaments forming process in resistive switching memory devices
  • Authors: Guo Tao, Hosameldeen Elshekh, Zhou Yu, Bo Yu, Dan Wang, Mayameen S. Kadhim, Yuanzheng Chen, Wentao Hou, Bai Sun
    Journal: Materials Today Communications
    Year: 2019
The pH-controlled memristive effect in a sustainable bioelectronic device prepared using lotus root
  • Authors: Li T, Y. Xu, M. Lei, Y. Zhao, B. Sun, Hosameldeen Elshekh, L. Zheng, X. Zhang, W. Hou
    Journal: Materials Today Sustainability
    Year: 2020

 

 

Md Wahadoszamen | Experimental methods | Best Researcher Award

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Prof. Dr. Md Wahadoszamen | Experimental methods | Best Researcher Award

Professor of Physics at University of Dhaka, Bangladesh

Profile🎓

Early Academic Pursuits 🎓

Dr. Md. Wahadoszamen embarked on his academic journey at the University of Dhaka, Bangladesh, where he earned his BSc in Physics (April 1999) and MSc in Physics (December 2000). Driven by his passion for material science, he pursued further studies at Hokkaido University, Japan, where he earned his PhD in Material Science in March 2006. His academic pursuits laid a solid foundation in experimental and theoretical laser physics, biophotonics, and nanophotonics, which would become central to his future research.

Professional Endeavors and Research Focus 🔬

Dr. Wahadoszamen’s career spans a broad spectrum of prestigious academic institutions across the globe. He joined the University of Dhaka as a Lecturer in 2006, eventually advancing to the position of Professor in May 2016. His academic role at the University of Dhaka has been complemented by positions at Kwansei Gakuin University in Japan, Carnegie Mellon University in the United States, and VU University Amsterdam in the Netherlands. These international engagements have enriched his research and expanded his academic influence globally.

His primary research interests lie at the intersection of laser physics, optical physics, and biophotonics. Specifically, Dr. Wahadoszamen has specialized in Raman Spectroscopy, Surface-Enhanced Raman Spectroscopy (SERS), Laser-Induced Breakdown Spectroscopy (LIBS), and Z-Scan Techniques. His work involves developing advanced materials like monometallic and bimetallic nanocomposites and highly fluorescent carbon nanodots, which have numerous applications in fields such as materials science, photonics, and biomedical imaging.

Contributions and Research Impact 🌟

Dr. Wahadoszamen’s contributions to laser and nanophotonics have significantly advanced the understanding of molecular interactions and material properties under laser illumination. His work on laser spectroscopy has provided new insights into nanomaterials and their applications, particularly in biomedical diagnostics and environmental monitoring. The development of carbon nanodots with high fluorescence properties has opened up new avenues in bioimaging and sensor technology. His research also explores biophysical applications of lasers, specifically in studying biological systems at the molecular and cellular levels.Through his research, Dr. Wahadoszamen has influenced key sectors, particularly in the fields of optical spectroscopy, nanotechnology, and biophotonics, where his work on nanocomposites and optical sensors has the potential to impact various industries, from medicine to environmental monitoring.

Teaching Experience and Mentorship 📚

Dr. Wahadoszamen has been an influential educator, teaching advanced courses in Quantum Mechanics, Biophysics, and Laser Physics at institutions such as the University of Dhaka, Kwansei Gakuin University, and University of Tsukuba. His extensive teaching experience, especially in guiding graduate students and postdocs, demonstrates his commitment to cultivating the next generation of scientists. He has taught graduate-level courses like Advanced Laser Physics for MS students, focusing on cutting-edge topics in laser theory and spectroscopy. In addition, he has supervised and mentored numerous MSc and PhD students throughout his career, preparing them to conduct pioneering research in physics and material science.

Technical Skills and Expertise 🛠️

Dr. Wahadoszamen possesses a wide range of technical skills that are critical to his research success:

  • Raman Spectroscopy (including Surface-Enhanced Raman Spectroscopy)
  • Laser-Induced Breakdown Spectroscopy (LIBS)
  • Z-Scan and Stark Spectroscopy
  • Nanocomposite Fabrication, including both monometallic and bimetallic materials
  • Fluorescence Spectroscopy and Absorption Spectroscopy

His ability to develop and implement innovative experimental techniques has led to significant advancements in molecular and material sciences.

Legacy and Future Contributions 🌍

Dr. Wahadoszamen’s career reflects his global impact as a leader in laser physics and biophotonics. His research legacy continues to inspire both his students and the broader scientific community. As a Professor and researcher, he has not only contributed to the scientific literature but also fostered a culture of collaborative research, working with prominent scientists from across the world. With future research projects focused on quantum photonics, bioimaging, and advanced nanomaterials, his work promises to make even more groundbreaking contributions to the fields of material science and biophotonics.

Research Collaborations and Academic Citations 📈

Dr. Wahadoszamen’s international research collaborations with experts from VU University Amsterdam, Carnegie Mellon University, Moscow State University, and many others have elevated his research output. His ability to engage with leading researchers from diverse institutions allows him to stay at the cutting edge of nanophotonics and biophotonics. With over 1000 citations and numerous influential publications in high-impact journals, his academic reputation continues to grow. His contributions have made a lasting impact in nanomaterials, molecular photonics, and laser spectroscopy.

Academic Service and Leadership 🏅

In addition to his research and teaching, Dr. Wahadoszamen has taken on leadership roles, such as serving as the Secretary for the International e-Conference on Physics 2021 organized by the University of Dhaka. He has also been an active student advisor and treasurer for various organizations, showcasing his commitment to academic service and community engagement. His leadership in organizing conferences and guiding young researchers further highlights his influence within the academic community.

A Vision for the Future 🌠

As Dr. Wahadoszamen continues to build on his outstanding achievements, his future contributions to nanotechnology, biophotonics, and laser spectroscopy are poised to shape the next generation of scientific innovations. His commitment to cutting-edge research, combined with his dedication to education and mentoring, ensures that his legacy will endure. Through his ongoing research in nanocomposites, carbon nanodots, and bioimaging, Dr. Wahadoszamen is well-positioned to continue influencing not only academic circles but also the broader scientific and technological landscape in the years to come.

Top Noted Publications📖

  • Authors: Michal Gwizdala, Tjaart PJ Krüger, Md Wahadoszamen, J Michael Gruber, Rienk Van Grondelle
  • Journal: The journal of physical chemistry letters
  • Year: 2018

Identification of two emitting sites in the dissipative state of the major light harvesting antenna

  • Authors: Md Wahadoszamen, Rudi Berera, Anjue Mane Ara, Elisabet Romero, Rienk van Grondelle
  • Journal: Physical Chemistry Chemical Physics
  • Year: 2012

Laser Raman spectroscopy with different excitation sources and extension to surface enhanced Raman spectroscopy

  • Authors: Md Wahadoszamen, Arifur Rahaman, Nabil Md Rakinul Hoque, Aminul I Talukder, Kazi Monowar Abedin, AFM Yusuf Haider
  • Journal: Journal of Spectroscopy
  • Year: 2015

Rigidity and polarity effects on the electronic properties of two deep blue delayed fluorescence emitters

  • Authors: Christian M Legaspi, Regan E Stubbs, Md Wahadoszaman, David J Yaron, Linda A Peteanu, Abraham Kemboi, Eric Fossum, Yongli Lu, Qi Zheng, Lewis J Rothberg
  • Journal: The Journal of Physical Chemistry
  • Year: 2018

Charge transfer states in phycobilisomes

  • Authors: Md Wahadoszamen, Tjaart PJ Krüger, Anjue Mane Ara, Rienk Van Grondelle, Michal Gwizdala
  • Journal: Biochimica et Biophysica Acta (BBA)-Bioenergetics
  • Year: 2020

 

 

Robert CHEHAB | Experimental methods | Best Innovation Award

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Dr.Robert CHEHAB | Experimental methods | Best Innovation Award

Accelerator physicist at IN2P3/CNRS in France

Dr. Robert Chehab, born on October 22, 1937, in Alexandria, Egypt, is a renowned physicist specializing in accelerator physics. He holds French nationality and has had a prestigious academic and scientific career. Dr. Chehab completed his engineering degree from the prestigious École Nationale Supérieure des Télécommunications (now TELECOM-Paris-Tech) in 1963, followed by a PhD in Physical Sciences from Université d’Orsay in 1975. His work has been instrumental in advancing our understanding of positron sources, channeling radiation, and radiation physics. Over his career, he has collaborated with leading institutions such as CERN, KEK, DESY, and SLAC. As a scientist and educator, he has mentored PhD students in radiation and positron source research. Fluent in five languages, Dr. Chehab has contributed significantly to accelerator physics research globally.

Profile:

Education:

Dr. Robert Chehab’s academic journey began at the École Nationale Supérieure des Télécommunications (ENST), now known as TELECOM-Paris-Tech, where he obtained his engineering degree in 1963. His rigorous technical education at ENST laid the foundation for his subsequent focus on accelerator physics. In 1975, he earned his PhD (Docteur-Ingénieur en Sciences Physiques) from the Université d’Orsay. His PhD work explored fundamental concepts in radiation physics and beam dynamics, setting the stage for a prolific research career. Throughout his educational journey, Dr. Chehab showed a deep understanding of complex scientific phenomena such as Cherenkov radiation, positron sources, and channeling radiation, positioning himself as a leading figure in his field. His multidisciplinary expertise has also allowed him to maintain fluency in French, English, Italian, Russian, and Arabic, further enhancing his global scientific impact.

Professional experience:

Dr. Robert Chehab has accumulated extensive experience in both academic and international research environments. He has spent a significant portion of his career at Université Paris-Saclay, where he has led various research projects on accelerator physics. Dr. Chehab has worked in prestigious laboratories worldwide, including extended stays at KEK in Japan, where he conducted research on positron sources and channeling radiation. He also contributed to experiments at DESY in Germany, focusing on transition radiation, and collaborated with BINP-Novosibirsk on channeling radiation studies. His leadership at CERN, particularly in the WA 103 experiment, has cemented his reputation as a leader in accelerator and radiation physics. Additionally, Dr. Chehab has supervised PhD students and played a critical role in mentoring the next generation of scientists.

Research focus:

Dr. Robert Chehab’s research focuses primarily on accelerator physics, with an emphasis on radiation studies. His work spans various topics, including positron sources, channeling radiation, Cherenkov radiation, transition radiation, and photoemission. He has been actively involved in understanding and developing novel radiation physics techniques for advanced accelerator applications. Dr. Chehab’s research also delves into beam dynamics and RF deflectors, expanding the theoretical and practical frameworks of accelerator science. His notable collaborations with CERN on positron source development for the LEP experiment and SLAC on crystal radiator damage tests have pushed the boundaries of what is known about particle interactions with radiation. His work is essential for innovations in particle accelerators, helping to develop the technology used in numerous high-energy physics experiments.

Awards & Honor:

Throughout his distinguished career, Dr. Robert Chehab has been recognized for his contributions to accelerator physics and radiation studies. He has been involved in numerous international collaborations with esteemed institutions such as CERN, KEK, SLAC, and DESY, where his innovative research in positron sources and radiation physics has earned him accolades. Dr. Chehab’s leadership in major projects, such as the LEP positron source collaboration at CERN, has further solidified his stature in the scientific community. His research has been published in leading journals like Nuclear Instruments and Methods, Physical Review, and Physics Letters. While his awards and recognitions are primarily rooted in his research, his contribution to academic mentorship, especially his guidance of PhD students in advanced radiation physics, has been equally commendable. His work continues to impact both experimental methods and the broader scientific community.

Publication Top Notes:

  • From bremsstrahlung to channeling radiation: A promising way for positron generation
    Chehab, R.
    Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 2024, 1060, 169056
    Citations: 0
  • Advantages of hybrid positron sources with granular converters
    Chehab, R., Chaikovska, I., Alharthi, F., Wallon, S., Sievers, P.
    Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 2024, 1060, 168994
    Citations: 0
  • Benchmarking the FCC-ee positron source simulation tools using the SuperKEKB results
    Alharthi, F., Chaikovska, I., Chehab, R., Miyahara, F., Mytrochenko, V.
    Journal of Physics: Conference Series, 2024, 2687(2), 022010
    Citations: 0
  • Radiation in oriented crystals: Innovative application to future positron sources
    Soldani, M., Alharthi, F., Bandiera, L., Sytov, A., Tikhomirov, V.
    Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 2024, 1058, 168828
    Citations: 1
  • Crystal-based pair production for a lepton collider positron source
    Bandiera, L., Bomben, L., Camattari, R., Tikhomirov, V., Vallazza, E.
    European Physical Journal C, 2022, 82(8), 699
    Citations: 6
  • Positron sources: From conventional to advanced accelerator concepts-based colliders
    Chaikovska, I., Chehab, R., Kubytskyi, V., Hogan, M.J., Martyshkin, P.
    Journal of Instrumentation, 2022, 17(5), P05015
    Citations: 12
  • HE-LHC: The High-Energy Large Hadron Collider: Future Circular Collider Conceptual Design Report Volume 4
    Abada, A., Abbrescia, M., AbdusSalam, S.S., Zupan, J., Zurita, J.
    European Physical Journal: Special Topics, 2019, 228(5), pp. 1109–1382
    Citations: 159
  • FCC-hh: The Hadron Collider: Future Circular Collider Conceptual Design Report Volume 3
    Abada, A., Abbrescia, M., AbdusSalam, S.S., Zupan, J., Zurita, J.
    European Physical Journal: Special Topics, 2019, 228(4), pp. 755–1107
    Citations: 501
  • FCC Physics Opportunities: Future Circular Collider Conceptual Design Report Volume 1
    Abada, A., Abbrescia, M., AbdusSalam, S.S., Zupan, J., Zurita, J.
    European Physical Journal C, 2019, 79(6), 474
    Citations: 540
  • FCC-ee: The Lepton Collider: Future Circular Collider Conceptual Design Report Volume 2
    Abada, A., Abbrescia, M., AbdusSalam, S.S., Zupan, J., Zurita, J.
    European Physical Journal: Special Topics, 2019, 228(2), pp. 261–623
    Citations: 619

Conclusion:

Dr. Robert Chehab’s extensive experience, significant contributions to accelerator physics, and international collaborations make him a strong candidate for the Best Researcher Award. His mentorship and prolific publication record add to his credentials. To further elevate his impact, engaging with newer fields of research and amplifying his public outreach would strengthen his candidacy for future recognitions.

 

Priyanka Sahu | Experimental methods | Young Scientist Award

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Dr. Priyanka Sahu | Experimental methods | Young Scientist Award

Assistant Professor at Rajiv Gandhi University of Knowledge of Technologies-RK Valley (AP-IIIT RK Valley), India

Dr. Priyanka Sahu is an accomplished academic and researcher, currently serving as an Assistant Professor in the Department of Electronics and Communication Engineering at Rajiv Gandhi University of Knowledge Technologies (AP-IIIT), Idupulapaya, Andhra Pradesh. With a solid foundation in Physics and Astronomy (Materials Science), she holds an M.Tech degree from NIT Rourkela and a Ph.D. from IIT Indore. Her research focuses on the development of high entropy alloys and soft magnetic materials, with expertise in experimental methodologies such as sol-gel auto-combustion and mechanical alloying. Dr. Sahu has published numerous high-impact papers, presented at international conferences, and received prestigious accolades like the Best Researcher Award and Best Oral Presentation. She is a passionate educator and an innovative thinker, contributing significantly to both research and academia.

Profile:

Education

Dr. Priyanka Sahu has pursued an impressive academic journey, earning her Ph.D. in Materials Science from the Indian Institute of Technology Indore (IITI) in 2023, where her dissertation focused on developing and characterizing high-entropy soft magnetic alloys. She holds an M.Tech (Research) degree in Physics and Astronomy with a specialization in Materials Science from the National Institute of Technology Rourkela (NITR) in 2017, during which she studied the electrical and magnetic properties of modified strontium hexaferrite. Prior to this, she completed her Bachelor of Engineering in Electronics and Telecommunication at the Government Engineering College Bilaspur in 2014, following a diploma in the same discipline from the Government Polytechnic College Ambikapur in 2011. Throughout her academic journey, Dr. Sahu has consistently maintained high honors and distinctions, showcasing her dedication to research and learning.

 

Professional experience

Dr. Priyanka Sahu has accumulated diverse teaching and research experience. She is currently serving as an Assistant Professor in the Department of Electronics and Communication Engineering at Rajiv Gandhi University of Knowledge Technologies (AP-IIIT), Idupulapaya, Andhra Pradesh, since March 2024. Prior to this, Dr. Sahu worked as a Teaching Assistant and researcher at IIT Indore from 2017 to 2023, during which she handled multiple labs and courses related to physical metallurgy and material science. Her research experience also includes working at NIT Rourkela in a Physics Laboratory. Dr. Sahu has expertise in handling various high-end instruments such as X-ray diffraction (XRD), Scanning Electron Microscopy (SEM), and Differential Scanning Calorimetry (DSC), which are crucial in material characterization. She has also participated in numerous national and international conferences as a presenter and invited speaker, furthering her knowledge and sharing insights into her specialized research areas.

Research focus

Dr. Priyanka Sahu’s research is centered around the development of advanced materials, particularly high-entropy alloys (HEAs), soft magnetic materials, and magnetocaloric materials. Her work explores novel synthesis methods, including mechanical alloying and sol-gel auto-combustion, to develop new materials with superior thermal, magnetic, and electrical properties. Dr. Sahu has extensively studied the microstructural and magnetic behaviors of multi-component alloys, investigating the influence of elements like Si and Mn on phase evolution and magnetic properties. She also focuses on thermodynamic modeling using Redlich-Kister formalism and Miedema’s semi-empirical models for predicting phase formations in these alloys. Her research aims to apply theoretical models to experimental data for better material characterization, especially in high-entropy amorphous alloys. Dr. Sahu’s work is highly interdisciplinary, impacting fields like nanotechnology, metallurgy, and condensed matter physics.

Award and Recognition

Dr. Priyanka Sahu has received numerous accolades throughout her academic and professional career. She was awarded the prestigious “Best Researcher Award” at the 16th edition of International Research Awards in Atomic, Molecular, and Optical Physics in 2024. Her outstanding oral presentation in the “Progress in Metallurgy & Materials (ISPMM-2023)” at IIT Indore earned her a Best Oral Presentation award. Additionally, she secured the 1st runner-up spot in poster presentation during the Research and Industrial Conclave (RIC-2023) at IIT Indore. Dr. Sahu has also received multiple honorariums for her contributions to various programs such as the QIP program at IIT Indore and TEQIP-III in 2018. She was recognized for her early academic excellence with a merit scholarship at Government Polytechnic College Ambikapur, and she ranked 1st in class during her diploma years. These honors reflect her commitment to research and academia.

Publication Top Notes:

  • Synthesis and characterization of hydrogenated novel AlCrFeMnNiW high entropy alloy
    ✍️ SK Dewangan, VK Sharma, P Sahu, V Kumar
    📘 International Journal of Hydrogen Energy, 45(34), 16984-16991, 2020, cited 62 times
  • Investigating the effect of multiple grain–grain interfaces on electric and magnetic properties of [50 wt% BaFe12O19–50 wt% Na0.5Bi0.5TiO3] composite system
    ✍️ R Pattanayak, R Muduli, RK Panda, T Dash, P Sahu, S Raut, S Panigrahi
    📘 Physica B: Condensed Matter, 485, 67-77, 2016, cited 42 times
  • Microstructure and magnetic behavior of FeCoNi (Mn–Si) x (x= 0.5, 0.75, 1.0) high-entropy alloys
    ✍️ P Sahu, S Solanki, S Dewangan, V Kumar
    📘 Journal of Materials Research, 34(5), 829-840, 2019, cited 30 times
  • Dielectric, ferroelectric and impedance spectroscopic studies in TiO2-doped AgNbO3 ceramic
    ✍️ R Muduli, R Pattanayak, S Raut, P Sahu, V Senthil, S Rath, P Kumar, …
    📘 Journal of Alloys and Compounds, 664, 715-725, 2016, cited 21 times
  • Effect of grain size on electric transport and magnetic behavior of strontium hexaferrite (SrFe12O19)
    ✍️ P Sahu, SN Tripathy, R Pattanayak, R Muduli, N Mohapatra, S Panigrahi
    📘 Applied Physics A, 123, 1-10, 2017, cited 15 times
  • Microstructural, magnetic, and geometrical thermodynamic investigation of FeCoNi (MnSi) x (0.0, 0.1, 0.25, 0.5, 0.75, 1.0) high entropy alloys
    ✍️ P Sahu, S Samal, V Kumar
    📘 Materialia, 18, 101133, 2021, cited 7 times
  • Impact of Si and Mg on Microstructural and Magnetic Behavior of Fe-Co-Ni (Mg-Si)x (x = 0.00,0.1,0.2) Multicomponent Alloys
    ✍️ P Sahu, AS Bagri, MD Anoop, M Kumar, V Kumar
    📘 Silicon, 12, 893-902, 2020, cited 7 times
  • Microstructural, magnetic, and geometrical thermodynamic investigation of FeCoNi (MnSi) x (0.0, 0.1, 0.25, 0.5, 0.75, 1.0) high entropy alloys
    ✍️ P Sahu, S Samal, V Kumar
    📘 Materialia, 18, 101133, Patent NO
  • Microstructure, Non-isothermal Crystallization Kinetics and Magnetic Behaviour Study of [FeCoNi100-x(SiMn)x] High Entropy Amorphous Alloys Synthesized by …
    ✍️ P Sahu, S Samal, V Kumar
    📘 Metals and Materials International, 29(9), 2684-2709, 2023, cited 3 times
  • Phase Evolution and Soft Magnetic Behavior of Mechanically Alloyed Fe–Co–Ni Medium Entropy Alloy at Different Disk Angular Velocity
    ✍️ P Sahu, S Samal, V Kumar
    📘 Transactions of the Indian Institute of Metals, 76(11), 3065-3078, 2023, cited 2 times
  • Investigation of the structural, electrical, and magnetic behavior of Co3+-Ti4+ doped strontium hexaferrite: validation of measured and theoretical models
    ✍️ P Sahu, PK Sahu, S Panigrahi
    📘 Journal of Materials Science: Materials in Electronics, 35(10), 709, 2024, cited 1 time
  • Influence of Si and Mn on the Phase Formation, Crystallization Kinetics, and Enhanced Magnetic Properties of Mechanically Alloyed NiCoFe(SiMn)x High Entropy …
    ✍️ P Sahu, S Samal, V Kumar
    📘 Silicon, 15(12), 5367-5392, 2023, cited 1 time
  • An assessment of the mechanically alloyed equiatomic FeCoNiMnSi high entropy amorphous alloy for non-isothermal crystallization kinetics and magnetocaloric refrigeration …
    ✍️ P Sahu, S Samal, V Kumar
    📘 Materials Characterization, 216, 114269, 2024

Conclusion

Overall, Dr. Priyanka Sahu is a well-rounded researcher with a solid background in materials science, excellent technical skills, a significant publication record, and previous awards. Her contributions to the field of high entropy alloys and magnetocaloric materials are impressive and impactful. While focusing on securing research funding and pursuing interdisciplinary research could enhance her profile further, she is undoubtedly a deserving candidate for the “Best Researcher Award.”