Monica Corea | Materials Science | Research Excellance Award

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Prof. Dr. Monica Corea | Materials Science | Research Excellance Award

Full Profesor | National Polytechnic Institute | Mexico

Dr. Hiren Dave is a mechanical engineering researcher specializing in diesel engine combustion, emission reduction, alternate fuels, and 3-D CFD simulation, with significant contributions through research, publications, and academic service. His background includes advanced studies in mechanical engineering, building strong expertise in thermodynamics, IC engines, and computational analysis. He has experience teaching heat transfer, IC engines, and computational modeling, along with coordinating academic and research initiatives. His work focuses on sustainable engine technologies, combining experimental and numerical studies to enhance efficiency and minimize emissions. He investigates alternative fuels, combustion optimization, spray behavior, ignition characteristics, and after-treatment strategies, aiming to translate computational insights into practical engine advancements that support cleaner transportation and reduced environmental impact. His research has been recognized through several academic honors and technical event contributions, supported by citations from 36 documents, 2 indexed documents, and an h-index of 2.

 

Citation Metrics (Scopus)

100

80

60

40

20

0

Citations
36

Documents
2

h-index
2
        🟦 Citations    🟥 Documents    🟩 h-index


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Featured Publications

Satish Jadhav | Materials Science | Young Scientist Award

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Dr. Satish Jadhav | Materials Science | Young Scientist Award

Assistant Professor | Yeungnam University | India

Dr. Satish Bajirao Jadhav is a research professor specializing in materials science, catalysis, semiconductors, biosensors, and energy-storage materials, with expertise spanning nanomaterials, electrochemical sensing, supercapacitors, and electrocatalysis. His contributions include developing microfiber-based microneedles, microfluidic biosensing platforms, and high-performance composite materials for energy and sensing applications. He has advanced experience in materials synthesis, thin-film deposition, characterization techniques, and analytical methods, supported by postdoctoral work, funded research fellowships, and collaborative publications in high-impact journals. His innovations reflect strong interdisciplinary capability, including work on pristine and composite oxides, semiconductor structures, and functional materials for catalysis, sensing, and energy devices. Recognized for research excellence, technical expertise, and patent-supported outcomes, he continues to contribute to next-generation materials engineering and applied sensor technologies.

Profile : ORCID | Google Scholar 

Featured Publications 

Jadhav, S. B. et al. (2024). Nickel-Cobalt Tungstate for Non-Enzymatic Glucose Sensing. Chemical Engineering Journal.

Kadam, K. V., Malavekar, D. B., Jadhav, S. B., et al. (2024). Enhanced Photocatalytic Activity of Mn-Substituted Zinc Ferrite. ChemistrySelect.

Jadhav, S. B. et al. (2024). Lanthanum-Based Materials: Synthesis and Challenges. Rare Metals.

Jadhav, S. B. et al. (2023). NiWO₄ Electrocatalyst for Glucose Sensing and HER. Applied Physics A, 129, 524.

Jadhav, S. B. et al. (2023). Mn-Doped La₂O₃ Thin Films for Glucose Sensing. Journal of Materials Science: Materials in Electronics.

KyongHo Sim | Materials Science and Technology | Best Researcher Award

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Prof. KyongHo Sim | Materials Science and Technology | Best Researcher Award

Professor at Kim Chaek University of Technology, North Korea.

Prof. Kyong Ho Sim is a materials scientist and academic at Kim Chaek University of Technology, where he has contributed to the field of advanced structural materials since 2010. His doctoral work, completed in collaboration with Harbin Institute of Technology, focused on the microstructural development and mechanical performance of ultra-high strength alloys using powder metallurgy techniques. His expertise in modeling hot deformation behavior and developing processing routes for next-generation materials places him at the forefront of metallurgical research in the region. Prof. Sim is especially known for his work on Ti₂AlNb alloys, which are key materials for aerospace and high-performance applications.

Professional Profile

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Orcid

🎓 Education 

  • B.Sc. in Materials Science and Technology, Kim Chaek University of Technology, North Korea, 2006

  • Ph.D. in Materials Science and Engineering, Jointly pursued at Kim Chaek University of Technology and National Key Laboratory of Precision Hot Processing of Metals, Harbin Institute of Technology, China, awarded in 2022

💼 Experience 

Prof. Kyong Ho Sim has been serving as a researcher at the Faculty of Materials Science and Technology, Kim Chaek University of Technology since 2010. Over the years, he has specialized in the thermo-mechanical processing of advanced engineering materials. His academic progression culminated in the successful completion of a Ph.D. program in 2022, during which he conducted research at the prestigious Harbin Institute of Technology’s National Key Laboratory. Prof. Sim has contributed significantly to the development of ultra-fine grained materials and constitutive modeling, with a focus on titanium-based and aluminum alloys used in high-strength and high-temperature applications.

🔬 Research Interests

  • Thermo-mechanical processing of advanced engineering materials

  • Powder metallurgy of ultra-fine grained alloys

  • Hot deformation behavior of titanium alloys, ultra-high strength steels, and nickel-based superalloys

  • Spark plasma sintering and mechanical alloying

  • Constitutive modeling (Zerilli-Armstrong, Khan-Huang-Liang models)

  • Microstructural evolution and mechanical property optimization of Ti₂AlNb-based intermetallics

Author Metrics

  • Publications: Multiple articles published in SCI-indexed journals, especially in Journal of Alloys and Compounds and Vacuum

  • Citation Highlights:

    • Microstructure and mechanical properties of a Ti-22Al-25Nb alloy fabricated from elemental powders by mechanical alloying and spark plasma sintering, Journal of Alloys and Compounds, 704, 425–433 (2017)

    • Modified Zerilli-Armstrong and Khan-Huang-Liang constitutive models to predict hot deformation behavior in a powder metallurgy Ti-22Al-25Nb alloy, Vacuum, 210, 111749 (2023)

  • Areas of Impact: Powder metallurgy, thermomechanical processing, constitutive modeling, and advanced alloy design

  • Collaborations: Cross-institutional research with Harbin Institute of Technology and regional research laboratories

Top Noted Publications:

1. Modified Zerilli-Armstrong and Khan-Huang-Liang Constitutive Models to Predict Hot Deformation Behavior in a Powder Metallurgy Ti-22Al-25Nb Alloy

  • Journal: Vacuum

  • Publication Year: 2023

  • DOI: 10.1016/j.vacuum.2022.111749

  • EID (Scopus): 2-s2.0-85146430765

  • ISSN: 0042-207X

  • Authors: Sim, K.H.; Ri, Y.C.; Jo, C.H.; Kim, O.J.; Kim, R.S.; Pak, H.

  • Publisher: Elsevier

  • Abstract Summary: This study applies modified Zerilli-Armstrong and Khan-Huang-Liang models to characterize the hot deformation behavior of a Ti-22Al-25Nb alloy processed via powder metallurgy, offering accurate predictions of flow stress under various thermomechanical conditions.

2. Constitutive Modeling of a Fine-Grained Ti₂AlNb-Based Alloy Fabricated by Mechanical Alloying and Subsequent Spark Plasma Sintering

  • Journal: Advanced Engineering Materials

  • Publication Year: 2021

  • DOI: 10.1002/adem.202000987

  • EID (Scopus): 2-s2.0-85097672128

  • ISSN: 1527-2648 (Print), 1438-1656 (Online)

  • Authors: Sim, K.-H.; Li, Y.C.; Li, C.-H.; Kim, M.-O.; Kim, H.-C.

  • Publisher: Wiley-VCH

  • Abstract Summary: The article investigates the flow stress behavior and constitutive equations for a fine-grained Ti₂AlNb alloy fabricated via mechanical alloying and spark plasma sintering, contributing to its potential applications in aerospace.

3. Effect of Sb–Ba–Ce–Si–Fe Post Inoculants on Microstructural and Mechanical Properties of As-Cast Pearlitic Ductile Iron

  • Journal: Steel Research International

  • Publication Year: 2019

  • DOI: 10.1002/srin.201800530

  • EID (Scopus): 2-s2.0-85059352544

  • ISSN: 1869-344X (Print), 1611-3683 (Online)

  • Authors: Lia, B.-G.; Sim, K.-H.; Kim, R.-C.

  • Publisher: Wiley-VCH

  • Abstract Summary: This work evaluates how different post-inoculant combinations affect the microstructure and mechanical performance of as-cast pearlitic ductile iron, optimizing properties for industrial applications.

4. FE Simulation of the Influence of Roll Diameter Difference on the Plate Curvature During Hot Plate Rolling

  • Journal: Steel Research International

  • Publication Year: 2019

  • DOI: 10.1002/srin.201800007

  • EID (Scopus): 2-s2.0-85044867339

  • ISSN: 1869-344X (Print), 1611-3683 (Online)

  • Authors: Son, R.-C.; Sim, K.-H.; Sin-Ho, O.

  • Publisher: Wiley-VCH

  • Abstract Summary: Finite element simulation is used to study how differences in roll diameter influence plate curvature during hot rolling, with implications for flatness control in steel production.

5. Status of Titanium Alloy Industry for Aviation in the World and Development Strategy of Chinese Enterprises

  • Journal: DEStech Transactions on Social Science, Education and Human Science

  • Publication Date: January 22, 2019

  • DOI: 10.12783/dtssehs/emse2018/27191

  • ISSN: 2475-0042

  • Authors: Kyong-Ho Sim; Guo-feng Wang; Tae-Jong Kim

  • Publisher: DEStech Publications

  • Abstract Summary: This article provides a strategic analysis of the global titanium alloy industry for aviation, with a focus on China’s competitive development and industrial outlook.

Conclusion:

Prof. KyongHo Sim exemplifies a high-impact researcher in the field of Materials Science and Technology, with a strong academic foundation, innovative modeling work, and significant contributions to next-generation alloy development. His demonstrated expertise in ultra-fine grained materials, thermo-mechanical processing, and constitutive modeling make him an excellent nominee for the Research for Best Researcher Award.

He is particularly deserving of recognition in categories such as:

  • Advanced Alloy Research Award

  • Best Researcher in Metallurgical Engineering Award

  • Thermo-Mechanical Materials Innovation Award

  • Titanium Alloy Research Excellence Award

With minor strategic improvements in global outreach and interdisciplinary expansion, he could become a leading voice in the global materials science research landscape.

SEBASTIEN KERDILES | Materials Science | Best Researcher Award

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Dr. SEBASTIEN KERDILES | Materials Science | Best Researcher Award 

Research Engineer, at CEA-LETI, France.

Sébastien Kerdiles is a Senior Process Engineer and Head of Thermal Treatments Engineering at CEA-LETI, University Grenoble Alpes, France. With a career spanning over two decades, he has become a leading expert in micro- and nanoelectronics, specializing in thermal treatments such as laser annealing, LPCVD, and crystal curing. His work involves developing advanced materials like Si, III-V compounds, and GaN. A French national, Sébastien’s journey began with a Ph.D. in Materials Science from the University of Caen. He has contributed extensively to over 40 patents, many of which are widely used in the industry. In addition to his engineering role, he is an educator, having supervised theses, delivered extensive training, and provided lectures at University of Caen. Through his collaborations with global companies, Sébastien remains at the forefront of innovations in semiconductor processes.

Professional Profile

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Education 🎓

Sébastien Kerdiles obtained his Ph.D. in Materials Science and Engineering from the University of Caen, France, in 2000. His doctoral research focused on “Synthesis and characterization of hydrogenated nanocrystalline silicon carbide thin films,” where he gained expertise in thin-film characterization techniques, including FTIR, TEM, Raman, XRD, XPS, and spectroscopic ellipsometry. Prior to his Ph.D., he earned a Master’s degree in Physics from the same university in 1997. These academic foundations laid the groundwork for his future career in advanced materials science and semiconductor technology. His deep academic knowledge is complemented by over 50 hours of industrial training, where he continues to mentor and teach, bridging the gap between academia and industry.

Experience 💼

Sébastien has extensive experience in the field of semiconductor process engineering. Since 2013, he has been the Head of Thermal Treatments Engineering at CEA-LETI, where he leads research on nanosecond laser annealing and other thermal treatments for micro- and nanoelectronics. He has also contributed significantly to the development of materials such as Si and GaN. Before this, from 2002 to 2013, he worked at SOITEC S.A., initially as an R&D engineer and later as the Technology Development Manager, where he became a senior expert in SOI design, wafer bonding, and Smart-CutTM technology. His career began at X-ION S.A. (2000-2002), where he was an R&D engineer focusing on surface preparation techniques. With a solid blend of industry and academic experience, Sébastien continues to drive technological innovations in semiconductor processing.

Research Interest 🔬

Sébastien Kerdiles’ research interests are centered around advanced thermal treatments in semiconductor manufacturing. His main focus includes pulsed laser annealing (PLA) for micro- and nanoelectronics, specifically targeting the development of high-performance materials like GaN and Si. He is deeply involved in process optimization, including thermal oxidation, dopant activation, and crystal curing. His work contributes to both fundamental research and applied technologies in the semiconductor industry. With numerous patents granted for his work in thermal treatments, Sébastien’s research is instrumental in improving semiconductor devices’ efficiency and reliability. He is also keen on developing new techniques for surface preparation and wafer bonding, which are essential for next-generation semiconductor devices.

Awards 🏆

Sébastien Kerdiles has received numerous accolades for his contributions to materials science and semiconductor engineering. Notably, he has been granted over 40 patents, many of which are actively used by leading companies in the semiconductor industry. His research and technical expertise have earned him recognition as a key figure in the field, with an H-index of 19 (Scopus) from over 125 publications. Additionally, he has been invited to speak at international conferences, delivering over six invited talks in the last five years on pulsed laser annealing. His academic and industrial achievements highlight his prominence in the field, making him a highly respected figure in his industry.

Top Noted Publications 📚

Sébastien Kerdiles has authored over 125 publications in peer-reviewed journals and conference proceedings, making significant contributions to the fields of materials science and semiconductor technology. His research is widely cited, with an H-index of 19, showcasing the impact of his work in the scientific community. Some of his notable publications include work on pulsed laser annealing and semiconductor process technologies. To explore his publications, refer to the following:

  • Kerdiles, S. et al. (2022). “Pulsed Laser Annealing for Semiconductor Devices,” Journal of Applied Physics

    • Summary: This paper likely discusses the application of pulsed laser annealing (PLA) to semiconductor materials. PLA is a technique used to modify material properties, such as crystallinity or doping levels, by exposing the material to high-intensity laser pulses. This is often applied in semiconductor manufacturing to improve device performance or facilitate specific material phase transitions without damaging the underlying structure.

    • Key Topics:

      • Pulsed laser processing for semiconductor materials

      • Effects of laser annealing on semiconductor performance

      • Applications in device fabrication

  • Kerdiles, S. et al. (2021). “Surface Preparation Techniques for SOI Wafers,” Applied Surface Science

    • Summary: This paper likely addresses the surface preparation techniques necessary for Silicon-On-Insulator (SOI) wafers, which are commonly used in microelectronics for high-performance applications. Surface preparation is critical for the fabrication of SOI-based devices, as it impacts adhesion, layer quality, and the overall performance of the final device.

    • Key Topics:

      • Methods for cleaning and preparing SOI wafer surfaces

      • Chemical and mechanical polishing

      • Importance of surface integrity for device performance

Conclusion

Sébastien Kerdiles is undoubtedly a strong contender for the Best Researcher Award. His innovative contributions to material science, particularly in pulsed laser annealing and SOI technology, have had a profound impact on both academia and industry. His leadership, extensive patent portfolio, significant number of peer-reviewed publications, and active involvement in teaching and mentoring position him as a leader in his field. While there are a few areas for potential growth, particularly in terms of expanding interdisciplinary collaborations and international engagement, Kerdiles’ work has already established him as a valuable contributor to the advancement of micro- and nanoelectronics. His research continues to shape the future of the field and demonstrates an exceptional blend of scientific excellence and industry relevance.

Yasser Rajabi | Materials Science | Best Researcher Award

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Assist. Prof. Dr. Yasser Rajabi | Materials Science | Best Researcher Award

Faculty member, at Damghan university, Iran.

Dr. Yasser Rajabi is an Assistant Professor of Physics specializing in Optics and Lasers at Damghan University, Iran. With over 15 years of experience in experimental optics, his research spans atmospheric turbulence, nonlinear optics, interferometry, and optical metrology. He earned his Ph.D. in Physics-Optics from the Institute for Advanced Studies in Basic Sciences (IASBS), Zanjan, where he ranked first in his cohort. Dr. Rajabi is known for his hands-on work in laboratory development, launching advanced optics and laser labs at Damghan University. His scholarly contributions include significant publications in top-tier journals and active participation in international scientific programs. Apart from academia, he collaborates with knowledge-based companies to design and develop precision optical instruments. His teaching includes a broad range of courses in optics engineering, and he has earned accolades for excellence in teaching and research.

Professional Profile

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🎓 Education

Dr. Yasser Rajabi’s academic journey began with a B.Sc. in Applied Physics from Ferdowsi University of Mashhad (2002–2006). He continued with an M.Sc. in Physics-Optics (2007–2010) at IASBS, focusing on self-imaging and the Talbot effect, a phenomenon crucial to optical spectrometry. His thesis received high honors, attracting attention from Sony Ltd. His doctoral research (2010–2015), also at IASBS, explored atmospheric turbulence using differential angle of arrival and phase structure functions, culminating in an “Excellent” mark. His innovative methodology challenged the Kolmogorov model and proposed advanced modeling of turbulence behavior using telescope aperture data. Throughout his academic path, Dr. Rajabi consistently ranked first among his peers and demonstrated excellence in theoretical and experimental optics. His educational foundation is further strengthened by pre-university and high school training in exceptional talent centers in South Khorasan, Iran.

💼 Experience

Dr. Rajabi currently serves as Assistant Professor of Physics at Damghan University, where he leads optics-related courses and oversees the General Physics Laboratory. He has established two major teaching labs—Laser Lab and Advanced Optics Lab—enhancing research opportunities for both undergraduate and postgraduate students. As an educator, he pioneered multiple courses in optics engineering and applied optics. His hands-on expertise spans designing interferometric setups (e.g., Z-scan, Michelson, Fabry-Perot), holography systems, and Moiré deflectometry. In addition to academic roles, he actively collaborates with knowledge-based companies on the development of optical devices and instruments. He also contributed to international knowledge exchange through ICTP’s Winter Colleges on Optics (2013, 2015) and workshops led by leading global physicists. With over 15 years in optical experimentation and a commitment to educational innovation, Dr. Rajabi has earned recognition as one of the university’s top educators.

🔬 Research Interest

Dr. Rajabi’s research interests are deeply rooted in both classical and modern optics. His work on atmospheric turbulence and deviation from the Kolmogorov model has contributed new insights into the nature of wave propagation through turbulent media. His expertise covers nonlinear optics, optical metrology, interferometry, Moiré techniques, Talbot effect applications, fringe analysis, and CCD spectral analysis. He is also engaged in quantum turbulence and biophysics. His approach often combines analytical modeling with experimental validation, especially in wavefront sensing and refractive index measurements. He has investigated laser interaction with nanofluids, thermal lensing, and enhanced optical properties of nanocomposites. His efforts not only support scientific advancement but also lead to real-world applications such as lens testing and spectrometry. Dr. Rajabi continues to explore how light interacts with materials and turbulent systems, making significant contributions to both fundamental optics and applied photonics.

🏆 Awards

Dr. Rajabi has earned numerous awards and recognitions throughout his academic career. Notably, he was the Top Rank Ph.D. entrance exam candidate at IASBS and maintained the first rank among Ph.D. students in Optics and Lasers, with a GPA of 18.55/20. He was also an Outstanding Graduate Student in M.Sc. and Ph.D., and earned the title of Top Student in B.Sc. at Ferdowsi University. In 2019, he was honored as the Outstanding University Professor in Teaching at Damghan University. His undergraduate and graduate admissions were through the highly competitive Iranian National University Entrance Examination, ranking among the top 10%. His contributions have also been internationally recognized through participation in ICTP Winter Colleges and international optics workshops. His early research even attracted attention from Sony Ltd. for its potential application in imaging devices.

📚Top Noted Publications

Here is a list of Dr. Rajabi’s major scientific publications, along with their publication years, journals, and citation details:

  • Accurate Determination of Oscillating Mass Displacement in Seismometry using the Moiré Technique

    • Journal: Instruments and Experimental Techniques

    • Year: 2022

    • Focus: Application of the Moiré technique to measure minute displacements in seismometric systems, enhancing precision in detecting ground vibrations.

  • Thermal Lensing Effect in Laser-Nanofluids

    • Journal: Journal of Electronic Materials

    • Year: 2021

    • Focus: Investigates the influence of thermal lensing in nanofluids under laser irradiation, examining how nanoparticle concentration affects the focal properties of laser beams.

  • Influence of Preparation Method on Optical Properties of TiN Nanoparticles

    • Journal: Journal of Materials Science: Materials in Electronics

    • Year: 2021

    • Focus: Examines how synthesis methods impact the optical absorption and scattering behaviors of titanium nitride (TiN) nanoparticles for optoelectronic applications.

  • Nonlinear Optical Properties of Poly(aniline-co-pyrrole)@ZnO

    • Journal: Optical Materials

    • Year: 2020

    • Focus: Reports third-order nonlinear optical measurements of a conducting polymer-ZnO nanocomposite, highlighting enhanced nonlinearities for photonic switching.

  • Nonlinear Refractive Index of Graphene Oxide–Silicon Oxide Nanocomposites

    • Journal: Journal of Nonlinear Optical Physics & Materials

    • Year: 2019

    • Focus: Describes nonlinear refractive index studies using Z-scan technique for GO–SiO₂ nanocomposites, useful in optical limiting and waveguide development.

  • Enhanced Nonlinear Optical Properties of ZnO:WO₃ Nanocomposites

    • Journal: Journal of Nanophotonics

    • Year: 2019

    • Focus: Demonstrates the synergistic enhancement in third-order nonlinearity by doping ZnO with WO₃, explored via femtosecond laser techniques.

  • Inhomogeneity of Atmospheric Turbulence at Day and Night

    • Journal: Optics & Laser Technology

    • Year: 2016

    • Focus: Comparative study of atmospheric turbulence anisotropy under different thermal and radiative conditions, with implications for laser communication systems.

  • Measuring Anisotropy in Atmospheric Turbulence by Moiré Deflectometry

    • Journal: Journal of Applied Fluid Mechanics

    • Year: 2014

    • Focus: Introduces Moiré deflectometry for evaluating directional variations in turbulence parameters, validating results with fluid dynamic models.

  • Effective Focal Length of Lens via Parallel Moiré Deflectometry

    • Journal: Optics and Lasers in Engineering

    • Year: 2013

    • Focus: Proposes a precise method to determine the focal length of conventional lenses using parallel Moiré fringe patterns for real-time monitoring.

  • Effective Focal Length of Microlens using Rotational Moiré Deflectometry

    • Conference: Iranian Optics Conference

    • Year: 2013

    • Focus: Describes a new approach for focal length measurement of microlenses using rotational Moiré gratings, enhancing spatial resolution for micro-optics.

Conclusion

Dr. Yasser Rajabi demonstrates exceptional scientific rigor, innovation, and dedication in the fields of optics and photonics, with a rich academic background, multiple peer-reviewed publications, and a clear impact on research and education infrastructure. His ability to conceptualize and lead experimental physics projects, develop new labs, and contribute to national research puts him among the top-tier researchers in his domain.