Ziyao Jie | Experimental methods | Best Researcher Award

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Dr. Ziyao Jie | Experimental methods | Best Researcher Award

Postdoc at State Grid Jibei Electric Power Co., Ltd. Research Institute in China

Ziyao Jie is a postdoctoral researcher at the State Grid Jibei Electric Power Research Institute. He holds a Ph.D. in Electrical Engineering from Tsinghua University, where his research centered on the microwave plasma-based synthesis of nanomaterials for lithium-ion battery applications. Throughout his academic career, Ziyao has made notable contributions to sustainable energy and plasma science, with a focus on improving energy storage technologies. His work on graphene-coated silicon nanomaterials addresses critical issues in battery performance, such as energy capacity and cycling stability. Ziyao’s research has been widely recognized, with multiple patents and publications in high-impact journals.

Profile:

Education:

Ziyao Jie earned his Ph.D. in Electrical Engineering from Tsinghua University, where he specialized in plasma science and nanomaterials synthesis under the guidance of Professor Guixin Zhang. His doctoral thesis focused on the development of microwave plasma methods for producing graphene-coated silicon nanoparticles, designed to enhance lithium-ion battery performance. During his studies, Ziyao gained a comprehensive understanding of high-voltage technologies, nanomaterial properties, and energy storage solutions, which equipped him to tackle real-world challenges in sustainable energy. His academic excellence is reflected in his deep knowledge of plasma diagnostics and high-temperature material synthesis.

Professional Experience:

Ziyao Jie has amassed significant experience in plasma science and energy storage. Following his doctoral research at Tsinghua University, where he developed innovative methods for synthesizing advanced materials for batteries, he continued as a postdoctoral researcher at the State Grid Jibei Electric Power Research Institute. His current work focuses on high-voltage and energy storage systems, contributing to the development of large-scale, sustainable energy solutions. Ziyao has collaborated on key projects such as the Beijing Science and Technology Planning Project, and his expertise spans the areas of nanomaterial synthesis, waste treatment with plasma, and renewable energy applications.

Research focus:

Ziyao Jie’s research focuses on the intersection of plasma science, nanomaterials, and sustainable energy. His primary area of interest is the synthesis of nanomaterials using microwave plasma technologies, with a particular focus on developing advanced materials for energy storage, such as graphene-coated silicon nanoparticles for lithium-ion batteries. His work aims to address key challenges in energy density, stability, and scalability for future battery technologies. Ziyao is also involved in developing plasma-based waste treatment systems, including medical waste management, using high-temperature plasma torches. His research is distinguished by its potential to revolutionize both energy storage and environmental sustainability.

Awards and Honors:

Ziyao Jie has received numerous accolades for his groundbreaking work in plasma science and nanomaterials. His research on microwave plasma-based synthesis earned him recognition in energy storage circles, particularly for his contributions to improving lithium-ion battery technology. Ziyao was a participant in the Beijing Science and Technology Planning Project, which recognized his innovative work on high-energy and high-voltage technologies. Additionally, his patented inventions, which include advanced methods for medical waste treatment and nanomaterial applications, have further established his reputation as a leading researcher. Ziyao’s contributions have also led to high citation indices, highlighting his influence in the academic community.

Publication Top Notes:

  • Mechanisms of Gas Temperature Variation of the Atmospheric Microwave Plasma Torch
    Z. Jie, C. Liu, S. Huang, G. Zhang
    Journal of Applied Physics, 129 (23), 2021
    Citations: 12
  • Microwave Plasma Torches for Solid Waste Treatment and Vitrification
    Z. Jie, C. Liu, D. Xia, G. Zhang
    Environmental Science and Pollution Research, 30 (12), 32827-32838, 2023
    Citations: 10
  • Imaging Diagnostics and Gas Temperature Measurements of Atmospheric-Microwave-Induced Air Plasma Torch
    S. Huang, C. Liu, Z. Jie, G. Zhang
    IEEE Transactions on Plasma Science, 48 (6), 2153-2162, 2020
    Citations: 10
  • Polymer Dielectrics with Outstanding Dielectric Characteristics via Passivation with Oxygen Atoms through C–F Vacancy Carbonylation
    T.Y. Wang, X.F. Li, Z. Jie, B.X. Liu, G. Zhang, J.B. Liu, Z.M. Dang, Z.L. Wang
    Nano Letters, 23 (18), 8808-8815, 2023
    Citations: 8
  • An Atmospheric Microwave Plasma-Based Distributed System for Medical Waste Treatment
    Z. Jie, C. Liu, D. Xia, G. Zhang
    Environmental Science and Pollution Research, 30 (17), 51314-51326, 2023
    Citations: 6
  • Surface-Wave-Sustained Plasma Synthesis of Graphene@Fe–Si Nanoparticles for Lithium-Ion Battery Anodes
    Z. Jie, Z. Zhang, X. Bai, W. Ma, X. Zhao, Q. Chen, G. Zhang
    Applied Physics Letters, 123 (11), 2023
    Citations: 3
  • Determination of 915-MHz Atmospheric Pressure Air Microwave Plasma Torch (MPT) Parameters
    Z. Jie, C. Liu, D. Xia, Z. Zhang, X. Zhao, G. Zhang
    IEEE Transactions on Plasma Science, 51 (2), 456-465, 2023
    Citations: 2
  • The Treatment of Medical Waste by Atmospheric Microwave Plasma
    D. Xia, C. Liu, Z. Jie, G. Zhang
    2021 IEEE International Conference on Plasma Science (ICOPS), 2021
    Citations: 2
  • Microwave Plasma Torch for Solid Waste Treatment
    Z. Jie, C. Liu, D. Xia, G. Zhang
    IET Digital Library, 2021
    Citations: 2
  • Continuous Batch Synthesis with Atmospheric-Pressure Microwave Plasmas
    Z. Jie, T.Y. Wang, S. Huang, X. Bai, W. Ma, G. Zhang, N. Luo
    iScience, 27 (8), 2024
    Citations: N/A

Conclusion:

Ziyao Jie is a strong candidate for the Best Researcher Award, with his groundbreaking contributions in plasma science and energy storage technologies. His research has direct implications for sustainable energy solutions, positioning him at the forefront of innovations in high-energy physics and computational science. His achievements, particularly his patents and numerous high-impact publications, showcase his potential to make lasting contributions to academia and industry, making him highly suitable for this prestigious award.

 

Jamshid Moghadasi | Interactions and fields | Best Researcher Award

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Assoc Prof Dr. Jamshid Moghadasi | Interactions and fields | Best Researcher Award

Associate Professor in Petroleum Engineering at Petroleum University of Technology in Iran

Dr. Jamshid Moghadasi, a renowned expert in petroleum engineering, has been a professor at the Petroleum University of Technology in Ahwaz, Iran, since 1990. His vast experience spans both academia and industry, particularly in enhanced oil recovery (EOR), formation damage, and multiphase flow dynamics. Dr. Moghadasi holds multiple MSc degrees in petroleum engineering, industrial engineering, and management, and earned his Ph.D. in petroleum engineering from the University of Surrey in 2003. His research has significantly impacted the oil and gas industry, contributing to innovations in water injection and formation damage control in porous media. He has managed major projects such as the Ghachsaran oilfield EOR and is a prominent figure in Iranian and international petroleum engineering communities, with active membership in societies and organizations like the Society of Petroleum Engineers.

Profile:

Google scholar

Education:

Dr. Moghadasi’s educational journey began with a Bachelor of Chemical Engineering in 1989 from the Abadan Institute of Technology, Ahwaz, Iran. He further pursued advanced studies, obtaining an MSc in Petroleum Engineering from the Petroleum University of Technology in 1995. His thesis focused on optimizing cementing operations in Iranian oilfields. In 1996, he earned a second MSc in Industrial Engineering from Mazandran University of Technology, with research centered on the engineering economy of unleaded gasoline production. His academic achievements culminated in a Ph.D. in Petroleum Engineering from the University of Surrey, UK, in 2003. His doctoral research explored particle movement and scale formation in porous media during water injection, offering insights into reservoir management and enhanced oil recovery techniques. Dr. Moghadasi’s diverse academic background provides a solid foundation for his expertise in petroleum engineering and industrial applications, contributing to his leadership in both research and project management.

Professional experience:

Dr. Jamshid Moghadasi has had an illustrious career spanning over three decades in both academic and practical roles within the oil and gas industry. Since 1990, he has been a professor at the Petroleum University of Technology, Ahwaz, specializing in reservoir engineering, drilling fluids, and enhanced oil recovery (EOR). Dr. Moghadasi also held leadership positions as the Head of Petroleum Engineering Department, Dean of Petroleum Engineering Faculty, and project manager for EOR initiatives at the Ghachsaran oilfield. His international experience includes a sabbatical at the University of Calgary and visiting research roles at the University of Surrey. Beyond teaching, he has been instrumental in organizing key conferences in nanotechnology and petroleum engineering. His extensive background in research and project management has earned him recognition as a thought leader in petroleum engineering, contributing to major advancements in oil recovery techniques and reservoir management strategies.

Research focus:

Dr. Jamshid Moghadasi’s research primarily focuses on enhancing oil recovery methods, investigating formation damage, and improving multiphase flow dynamics in oil reservoirs. His work on optimizing water injection and addressing scale formation in porous media has been pivotal for increasing oil production efficiency. He has contributed significantly to the understanding of fine migration in porous media and its impact on reservoir performance. Dr. Moghadasi is also recognized for his expertise in well completion techniques, cementing optimization, and hydraulic fracturing. His more recent research delves into the application of nanotechnology in oil recovery, studying how nanoparticles can enhance fluid properties and improve oil extraction processes. His work on electrostatic forces between suspension particles and gas well liquid loading further enhances his comprehensive approach to addressing complex challenges in the petroleum industry.

Awards and Honors:

Dr. Jamshid Moghadasi has earned numerous awards and honors for his contributions to petroleum engineering. Notably, he received the Distinguished Researcher Award from the Petroleum University of Technology in both 2007 and 2010, highlighting his consistent excellence in research and innovation. His groundbreaking work was also recognized with the Khuzestan Technical University Research Award in 2014. In 2004, his article was ranked among the top publications in the Journal of Petroleum Science and Engineering by Elsevier. Dr. Moghadasi’s leadership in organizing major conferences, such as the First International Congress of Nanotechnology and the National Petroleum Engineering Congress, has further solidified his reputation in the field. His professional involvement in the Society of Petroleum Engineering and Iranian Petroleum Engineering Society also showcases his commitment to advancing the industry through both academic and professional channels.

Publication Top Notes:

  • Scale formation in Iranian oil reservoir and production equipment during water injection
    J Moghadasi, M Jamialahmadi, H Müller-Steinhagen, A Sharif, …
    2003, 236 citations
  • Theoretical and experimental study of particle movement and deposition in porous media during water injection
    J Moghadasi, H Müller-Steinhagen, M Jamialahmadi, A Sharif
    2004, 201 citations
  • Viscosity of pure carbon dioxide at supercritical region: Measurement and correlation approach
    E Heidaryan, T Hatami, M Rahimi, J Moghadasi
    2011, 199 citations
  • An experimental investigation of polysilicon nanoparticles’ recovery efficiencies through changes in interfacial tension and wettability alteration
    A Roustaei, J Moghadasi, A Iran, H Bagherzadeh, A Shahrabadi
    2012, 196 citations
  • Model study on the kinetics of oil field formation damage due to salt precipitation from injection
    J Moghadasi, H Müller-Steinhagen, M Jamialahmadi, A Sharif
    2004, 188 citations
  • Formation damage due to scale formation in porous media resulting from water injection
    J Moghadasi, M Jamialahmadi, H Müller-Steinhagen, A Sharif
    2004, 143 citations
  • New correlations to predict natural gas viscosity and compressibility factor
    E Heidaryan, J Moghadasi, M Rahimi
    2010, 134 citations
  • Surface functionalization of silica nanoparticles to improve the performance of water flooding in oil wet reservoirs
    S Azarshin, J Moghadasi, Z A Aboosadi
    2017, 123 citations
  • Scale Formation in Oil Reservoir and Production Equipment during Water Injection Kinetics of CaSO4 and CaCO3 Crystal Growth and Effect on Formation Damage
    J Moghadasi, M Jamialahmadi, H Müller-Steinhagen, A Sharif
    2003, 109 citations
  • A novel correlation approach for prediction of natural gas compressibility factor
    E Heidaryan, A Salarabadi, J Moghadasi
    2010, 107 citations
  • Formation damage in Iranian oil fields
    J Moghadasi, M Jamialahmadi, H Müller-Steinhagen, A Sharif, …
    2002, 107 citations

Conclusion:

Dr. Jamshid Moghadasi is an outstanding candidate for the Best Researcher Award based on his deep expertise, innovative research, leadership, and significant contributions to the field of petroleum engineering. His extensive academic work, coupled with real-world industrial applications, marks him as a leader in his field. While he could expand his impact into emerging energy sectors and sustainability efforts, his current body of work makes him highly deserving of recognition.

 

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.”

Meissam Noroozifar | Particle Experiments | Best Researcher Award

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Prof. Meissam Noroozifar | Particle Experiments | Best Researcher Award

Catalyst  at University of Toronto in Canada

Prof. Meissam Noroozifar is a distinguished chemist with over two decades of experience in teaching, research, and mentorship. He has made substantial contributions in applied chemistry, nanotechnology, renewable energy, and environmental protection. His research spans a wide range of fields, including nanomaterials, fuel cells, biofuel cells, and water purification. With over 250 peer-reviewed publications, Prof. Noroozifar has established himself as a leader in the chemistry and engineering communities. He has worked extensively with international collaborators and supervised numerous Ph.D. and M.Sc. students, fostering the development of future scientists. Currently, he is a senior research associate at the University of Toronto Scarborough.

Profile:

Education:

Prof. Noroozifar earned his Ph.D. in Chemistry from Shahid Beheshti University, Tehran, Iran, in 2002. His academic journey has been marked by significant contributions to both theoretical and practical aspects of chemistry. His doctoral research laid the foundation for his extensive career in nanomaterials and applied chemistry. Prof. Noroozifar’s education has been complemented by various sabbatical and visiting positions at prestigious institutions, further enriching his expertise and research capabilities.

Professional experience:

Prof. Noroozifar began his academic career as an Assistant Professor at the University of Sistan and Baluchestan (USB) in 2002, advancing to Associate Professor in 2006 and then University Professor by 2010. His roles have included visiting professorships and sabbaticals at the University of Toronto Scarborough and Carleton University. Since 2018, he has been a Senior Research Associate at UTSC, working with prominent labs. His career is marked by extensive supervision of Ph.D. and M.Sc. students and significant contributions to research and teaching in chemistry and applied chemistry.

Research interest:

Prof. Noroozifar’s research focuses on the synthesis and application of nanomaterials, including metallic and bimetallic aerogels, for sustainable energy solutions and environmental remediation. His work explores advanced electrochemical processes, such as CO2 reduction and fuel cell technologies. He is also known for his contributions to the development of new sensors and analytical methods for detecting pollutants and toxic substances in water and wastewater, combining his expertise in nanotechnology with environmental chemistry.

Award and Recognition:

Prof. Noroozifar has received multiple accolades for his outstanding research contributions. He was recognized as the Top Exemplary Researcher at USB in 2018 and received exemplary researcher awards from both USB and its Faculty of Science in 2004, 2009, and 2010. These awards highlight his significant impact in research and academia, showcasing his dedication to advancing the field of chemistry and applied sciences.

Publication Top Notes:

  • Simultaneous and sensitive determination of a quaternary mixture of AA, DA, UA, and Trp using a modified GCE by iron ion-doped natrolite zeolite-multiwall carbon nanotube
    ✍️ M Noroozifar, M Khorasani-Motlagh, R Akbari, MB Parizi
    📘 Biosensors and Bioelectronics, 28(1), 56-63, 2011, cited 198 times
  • Preparation of silver hexacyanoferrate nanoparticles and its application for the simultaneous determination of ascorbic acid, dopamine, and uric acid
    ✍️ M Noroozifar, M Khorasani-Motlagh, A Taheri
    📘 Talanta, 80(5), 1657-1664, 2010, cited 140 times
  • Investigation of a new electrochemical cyanide sensor based on Ag nanoparticles embedded in a three-dimensional sol–gel
    ✍️ A Taheri, M Noroozifar, M Khorasani-Motlagh
    📘 Journal of Electroanalytical Chemistry, 628(1-2), 48-54, 2009, cited 92 times
  • Novel fabrication of PdCu nanostructures decorated on graphene as excellent electrocatalyst toward ethanol oxidation
    ✍️ AS Douk, H Saravani, M Noroozifar
    📘 International Journal of Hydrogen Energy, 42(22), 15149-15159, 2017, cited 87 times
  • Adsorption behavior of Cr (VI) on modified natural zeolite by a new bolaform N, N, N, N′, N′, N′-hexamethyl-1, 9-nonanediammonium dibromide reagent
    ✍️ M Noroozifar, M Khorasani-Motlagh, MN Gorgij, HR Naderpour
    📘 Journal of Hazardous Materials, 155(3), 566-571, 2008, cited 85 times
  • Chemical synthesis and characterization of perovskite NdFeO3 nanocrystals via a co-precipitation method
    ✍️ M Khorasani-Motlagh, M Noroozifar, M Yousefi, S Jahani
    📘 International Journal of Nanoscience and Nanotechnology, 9(1), 7-14, 2013, cited 78 times
  • Flow injection analysis–flame atomic absorption spectrometry system for indirect determination of cyanide using cadmium carbonate as a new solid-phase reactor
    ✍️ M Noroozifar, M Khorasani-Motlagh, SN Hosseini
    📘 Analytica Chimica Acta, 528(2), 269-273, 2005, cited 78 times
  • Palladium aerogel as a high-performance electrocatalyst for ethanol electro-oxidation in alkaline media
    ✍️ MZ Yazdan-Abad, M Noroozifar, ARM Alam, H Saravani
    📘 Journal of Materials Chemistry A, 5(21), 10244-10249, 2017, cited 73 times
  • Specific extraction of chromium as tetrabutylammonium-chromate and spectrophotometric determination by diphenylcarbazide: speciation of chromium in effluent streams
    ✍️ M Noroozifar, M Khorasani-Motlagh
    📘 Analytical Sciences, 19(5), 705-708, 2003, cited 72 times
  • Solid-phase iodine as an oxidant in flow injection analysis: determination of ascorbic acid in pharmaceuticals and foods by background correction
    ✍️ M Noroozifar, M Khorasani-Motlagh
    📘 Talanta, 61(2), 173-179, 2003, cited 67 times

Conclusion:

Prof. Meissam Noroozifar is a strong candidate for the Best Researcher Award. His extensive body of research, diverse expertise, international experience, and mentorship of young researchers make him a deserving nominee. With his proven commitment to advancing scientific knowledge, especially in sustainable energy and environmental protection, his work has high relevance and impact. Strengthening his global outreach and focusing on commercial applications could further enhance his profile, but his current accomplishments alone make him highly qualified for the award.

Radomira Lozeva | Computational Methods | Best Researcher Award-3369

Published on by High Energy Physics

Dr.Radomira Lozeva| Computational Methods | Best Researcher Award

Dr Radomira Lozeva CNRS

Professional Profiles

Publications

Conclusion

Given her extensive research experience, significant contributions to nuclear physics, leadership in experiments, successful mentorship, and active engagement in the scientific community, Radomira Lozeva is highly suitable for both the Research for Community Impact Award and the Best Research Award. Her innovative work and dedication to advancing the field make her a strong contender for these prestigious recognitions.