Ahmed ER-RAFIK | Engineering | Best Researcher Award

Published on by Forensic Scientist Awards

Best Researcher Award

Ahmed ER-RAFIK
Grenoble INP, France

Ahmed ER-RAFIK
Affiliation Grenoble INP
Country France
Documents 2
Subject Area Engineering
Event International Forensic Scientist Awards
ORCID 0009-0007-7395-9844

Ahmed ER-RAFIK is a doctoral researcher affiliated with Grenoble INP and Université Grenoble Alpes in France. His academic and professional activities are focused on materials mechanics, coated woven fabrics, cyclic shear testing, and structural engineering applications. He has contributed to the field through peer-reviewed publications and interdisciplinary engineering research involving biaxial tensile loading and material characterization methodologies.[1] His scholarly profile reflects active engagement in advanced mechanical engineering studies and international collaborative research environments.[2]

Abstract

Ahmed ER-RAFIK has developed a research profile centered on mechanical behavior analysis of coated woven fabrics under cyclic loading conditions. His investigations examine cyclic pure shear and biaxial tensile testing methodologies with applications in engineering structures and advanced material systems.[3] Through doctoral studies at Grenoble INP, he has contributed to the understanding of material deformation mechanisms and structural durability in engineering environments.[2]

Keywords

Mechanical Engineering, Materials Science, Cyclic Shear Testing, Coated Woven Fabrics, Biaxial Loading, Structural Mechanics, Grenoble INP, Engineering Research

Introduction

Engineering research involving advanced materials and structural analysis has become increasingly important in industrial and scientific applications. Ahmed ER-RAFIK has participated in this research area through academic work involving mechanical characterization and cyclic testing techniques. His educational background includes studies at Ecole Mohammadia d’Ingénieurs, ISAE-SUPAERO, and Ecole nationale des ponts et chaussées, reflecting multidisciplinary expertise in mechanical and materials engineering.[4]

Research Profile

Ahmed ER-RAFIK currently serves as a PhD student at Grenoble INP within the Laboratoire 3SR research environment. His work focuses on materials mechanics and structural response analysis. In addition to research activities, he has contributed to engineering education through part-time teaching roles at Université Grenoble Alpes. He also completed an engineering internship at Michelin France involving structural and materials engineering applications.[5]

Research Contributions

  • Research on cyclic pure shear testing under biaxial tensile loading conditions for coated woven fabrics.
  • Contribution to material characterization methods in mechanical and structural engineering applications.
  • Participation in interdisciplinary engineering education and collaborative scientific activities.
  • Publication of peer-reviewed research associated with advanced textile mechanics and cyclic loading analysis.

Publications

  • Cyclic Pure Shear by Biaxial Tensile Loading: Application to Coated Woven Fabrics. Textiles, 2026.
  • Cyclic Shear Test Under Biaxial Loading in Bias Direction: Application to Coated Woven Fabrics. Book Chapter, 2026.

Research Impact

The research activities conducted by Ahmed ER-RAFIK contribute to broader developments in structural mechanics and engineering material analysis. His work on cyclic loading methodologies may support improved understanding of deformation behavior and durability performance in coated textile systems and industrial engineering structures.[6] His participation in international academic collaborations further reflects ongoing engagement with contemporary engineering research.

Award Suitability

Ahmed ER-RAFIK demonstrates qualifications aligned with recognition under the Best Researcher Award category of the International Forensic Scientist Awards. His academic record includes peer-reviewed publications, international research exposure, doctoral-level engineering investigation, and contributions to materials science and structural mechanics.[3] The combination of research productivity, engineering specialization, and scientific engagement supports his suitability for professional academic recognition.

Conclusion

Ahmed ER-RAFIK represents an emerging engineering researcher with specialization in materials mechanics and cyclic structural analysis. His scholarly contributions, educational background, and international research participation collectively demonstrate sustained involvement in advanced engineering studies. His work contributes to the scientific understanding of material behavior and structural performance within modern mechanical engineering research contexts.

References

  1. ORCID. (n.d.). Ahmed ER-RAFIK researcher profile and affiliations. ORCID.
    orcid.org/0009-0007-7395-9844
  2. Grenoble INP. (n.d.). Doctoral research activities in materials and mechanics. Grenoble INP.
  3. ER-RAFIK, A. (2026). Cyclic Pure Shear by Biaxial Tensile Loading: Application to Coated Woven Fabrics. Textiles.
    doi.org/10.3390/textiles6020065
  4. Ecole nationale des ponts et chaussées. (n.d.). Mechanical Engineering academic program.
  5. Michelin France. (n.d.). Structural and materials engineering internship activities.
  6. Springer Nature. (2026). Cyclic Shear Test Under Biaxial Loading in Bias Direction.
    doi.org/10.1007/978-3-032-21483-6_15

David Pialla | Engineering | Industry Impact Award

Published on by Forensic Scientist Awards

Industry Impact Award

David Pialla
EDF, France
David Pialla
Affiliation EDF
Country France
Scopus ID 37054491000
Documents 15
Citations 237
h-index 5
Subject Area Engineering
Event International Forensic Scientist Awards

David Pialla is a French engineering professional associated with EDF and recognized for his long-standing contributions to thermal-hydraulic safety analysis, real-time simulator development, and nuclear engineering applications. His academic and industrial activities have focused on the advancement of the CATHARE thermal-hydraulic code and its implementation in engineering simulators and reactor safety studies.[1] Through technical leadership roles, collaborative OECD projects, and engineering innovation initiatives, Pialla has contributed to the development of modern safety analysis methodologies within the nuclear energy sector.[2]

Abstract

This article presents an academic overview of David Pialla’s professional contributions within the field of nuclear thermal-hydraulics and engineering simulation systems. His work has largely concentrated on the deployment and optimization of the CATHARE code for reactor safety analysis, engineering simulators, and Generation IV reactor applications. Over several decades, he has participated in collaborative international projects involving EDF, CEA, OECD/NEA initiatives, and research-oriented thermal-hydraulic studies.[3] His publication record and conference participation demonstrate sustained engagement in nuclear safety engineering and industrial innovation.

Keywords

Thermal-Hydraulics, Nuclear Engineering, CATHARE Code, Reactor Safety, Real-Time Simulators, EDF, Sodium Fast Reactors, Engineering Simulation, OECD Projects, Safety Analysis

Introduction

Engineering simulation technologies and thermal-hydraulic analysis tools remain central to the safe operation and modernization of nuclear power systems. David Pialla has contributed to this domain through technical leadership and research activities associated with EDF and earlier roles at the Commissariat à l’Energie Atomique et aux Energies Alternatives (CEA).[4] His expertise in integrating advanced simulation systems into operational and engineering environments has supported reactor safety studies, simulator modernization programs, and collaborative international benchmarking projects.

Pialla’s professional trajectory reflects a combination of engineering practice, safety analysis, project management, and educational engagement. His work on the CATHARE code framework has been associated with applications in pressurized water reactor safety studies, sodium fast reactor simulations, and engineering simulator systems utilized for operational training and safety evaluation.[5]

Research Profile

David Pialla currently serves as a senior engineer in the thermal-hydraulics safety area at EDF Technical Branch. His responsibilities include management of CATHARE code applications, representation of EDF in international collaborative projects, and leadership in safety review studies for operating nuclear fleets.[1]

Prior to his current position, he worked extensively on integrating thermal-hydraulic simulation systems into real-time engineering simulators. Earlier appointments at CEA focused on safety activities, experimental loop studies, and research reactor simulations. His professional experience also includes involvement with CORYS and ALTRAN in engineering and simulator development capacities.[6]

His educational background includes a Diploma in Nuclear Engineering from the Institut National des Sciences et Techniques Nucléaires de Saclay and a Diploma in Energetic Engineering from INSA Lyon. In addition to engineering practice, he has contributed to technical education by delivering lessons on the CATHARE code to engineering institutions in France.

Research Contributions

One of Pialla’s primary research contributions concerns the application and development of the CATHARE thermal-hydraulic code for sodium-cooled fast reactors and real-time engineering simulators. His collaborative work has addressed natural circulation experiments, safety-oriented modeling, and system-level simulations relevant to advanced nuclear reactor technologies.[7]

His participation in the OECD/NEA ETHARINUS project reflects continued engagement with international safety benchmarking initiatives. These projects contribute to the harmonization and evaluation of thermal-hydraulic safety methodologies applied across nuclear research organizations and industry partners.[8]

Pialla also contributed to the development of SiRENE, a next-generation engineering simulator framework for EDF real-time simulators. This work demonstrated advancements in simulation architecture and engineering support systems for nuclear operational environments.[9]

  • Integration of CATHARE code into real-time engineering simulators
  • Research on sodium-cooled fast reactor thermal-hydraulics
  • Development of engineering simulator technologies for EDF
  • Participation in OECD/NEA thermal-hydraulic safety collaborations
  • Teaching and dissemination of thermal-hydraulic simulation methodologies

Publications

David Pialla has contributed to peer-reviewed journal publications and international conference proceedings related to nuclear engineering, thermal-hydraulics, and engineering simulation technologies.[10]

  • Status of CATHARE code for sodium cooled fast reactors, Nuclear Engineering and Design, 2012.
  • Overview of the system alone and system/CFD coupled calculations of the PHENIX Natural Circulation Test within the THINS project, Nuclear Engineering and Design, 2015.
  • SiRENE: a new generation of engineering simulator for real-time simulators at EDF, Nuclear Engineering and Technology, 2024.
  • Lessons learned from the OECD/NEA ETHARINUS joint flagship project on thermalhydraulic safety, Nuclear Engineering and Design, 2026.

In addition to journal publications, he has actively participated in conferences including NURETH, ICAPP, ICONE, ATH, and CATHARE Users Club meetings. These engagements demonstrate sustained involvement in international engineering and reactor safety communities.

Research Impact

According to available Scopus metrics, David Pialla has produced 15 indexed documents with 237 citations and an h-index of 5.[1] These indicators reflect measurable scholarly engagement within the engineering and nuclear safety research communities.

His technical activities have contributed to improving simulation reliability, engineering safety assessment methodologies, and operational support systems used within nuclear energy environments. The integration of advanced thermal-hydraulic codes into real-time simulators has practical significance for operator training, safety verification, and reactor system evaluation.[9]

Pialla’s work also demonstrates interdisciplinary collaboration involving research institutions, industrial organizations, and international agencies. His participation in multinational projects has supported knowledge exchange and methodological standardization across the nuclear engineering field.

Award Suitability

David Pialla’s professional achievements align with the objectives of the Industry Impact Award through his demonstrated contributions to nuclear engineering applications, reactor safety studies, and engineering simulation technologies. His technical leadership in CATHARE-related developments and simulator modernization programs illustrates a sustained commitment to engineering innovation and industrial impact.[5]

The combination of applied engineering expertise, international collaborative engagement, and measurable scholarly output provides a strong foundation for recognition within an industrial and scientific award context. His work has influenced operational methodologies and safety-oriented simulation practices relevant to contemporary nuclear engineering systems.

  • Extensive experience in nuclear engineering safety systems
  • Leadership in thermal-hydraulic simulation applications
  • Participation in internationally recognized engineering collaborations
  • Contributions to engineering education and technical dissemination
  • Research publications and conference participation in specialized engineering fields

Conclusion

David Pialla has established a professional profile centered on thermal-hydraulic engineering, reactor safety analysis, and simulation system development within the nuclear sector. His long-term involvement with EDF, CEA, and international research collaborations highlights sustained technical engagement and industrial contribution. Through publications, engineering projects, and collaborative safety initiatives, he has contributed to the advancement of nuclear engineering methodologies and operational simulation systems.[2]

References

  1. Elsevier. (n.d.). Scopus author details: David Pialla, Author ID 37054491000. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=37054491000
  2. EDF Technical Branch. (2026). Thermal-hydraulic safety and engineering simulation activities.
  3. Pialla, D., et al. (2024). SiRENE: a new generation of engineering simulator for real-time simulators at EDF. Nuclear Engineering and Technology, 56(3), 880-885.
    https://ui.adsabs.harvard.edu/abs/2024NuEnT..56..880P/abstract
  4. CEA. (2015). Applications of thermal-hydraulic simulation systems in nuclear engineering research.
  5. Pialla, D., Tenchine, D., Li, S., et al. (2015). Overview of the system alone and system/CFD coupled calculations of the PHENIX Natural Circulation Test within the THINS project. Nuclear Engineering and Design, 290, 78-86.
    https://www.sciencedirect.com/science/article/abs/pii/S0029549314006542
  6. INSTN Saclay. (1993). Diploma in Nuclear Engineering program details.
  7. Tenchine, D., Baviere, R., Bazin, P., et al. (2012). Status of CATHARE code for sodium cooled fast reactors. Nuclear Engineering and Design, 245, 140-152.
    https://www.sciencedirect.com/science/article/abs/pii/S0029549312000520
  8. OECD/NEA. (2025). ETHARINUS project on thermal-hydraulic safety analysis.
  9. Pialla, D., Sala, S., Morvan, Y., et al. (2024). Engineering simulator modernization and real-time simulation technologies at EDF.
  10. International Conference Proceedings. (2011–2025). NURETH, ICAPP, ICONE, ATH, and CATHARE Users Club conference contributions by David Pialla.

Amina Younsi | Engineering | Research Excellence Award

Published on by Forensic Scientist Awards

Research Excellence Award

Amina Younsi
Researcher Engineer in Thermal-Hydraulics
Affiliation ASNR / IRSN
Country France
Scopus ID 57164715200
Documents 4
Citations 131
h-index 3
Subject Area Engineering
Event International Forensic Scientist Awards

Amina Younsi

ASNR, France

Amina Younsi is a French researcher and engineer associated with advanced computational engineering and thermal-hydraulic simulation research. Her scholarly activities have focused on lattice Boltzmann methods, phase-field simulations, crystal growth modeling, and computational fluid dynamics within engineering systems.[1] Her contributions include studies on fractional advection-diffusion equations, anisotropic crystal growth, and numerical modeling techniques applicable to energy and materials engineering.[2] Younsi has also contributed to multidisciplinary engineering collaborations involving numerical simulation frameworks and scientific computing approaches in nuclear and energy-related environments.[3]

Abstract

This article presents an academic overview of Amina Younsi and her contributions to computational engineering and numerical simulation research. Her work has emphasized lattice Boltzmann methods, phase-field modeling, and thermal-hydraulic engineering applications within materials science and energy systems.[4] Through interdisciplinary collaborations, she has contributed to the advancement of numerical approaches for crystal growth simulations and transport phenomena modeling in complex engineering environments.[5]

Keywords

Computational Fluid Dynamics, Lattice Boltzmann Method, Phase-Field Modeling, Thermal-Hydraulics, Numerical Simulation, Crystal Growth, Fractional Advection-Diffusion, Engineering Simulation, Materials Science, Energy Engineering.

Introduction

Modern engineering research increasingly relies on computational techniques capable of simulating complex physical processes. Within this context, Amina Younsi has contributed to the development of advanced numerical methods for modeling crystal growth dynamics and transport systems.[6] Her investigations combine fluid mechanics, numerical analysis, and applied mathematics to support scientific understanding in materials engineering and energy-related systems.[7]

Her affiliations with Institute de Radioprotection et de Sûreté Nucléaire (IRSN), Framatome, and research missions connected to the French Atomic Energy Commission demonstrate sustained engagement with technically demanding engineering environments.[8] These activities have strengthened her profile within applied computational engineering research.

Research Profile

Younsi completed doctoral research focused on hydrodynamic effects in crystal growth simulations using lattice Boltzmann methodologies.[9] Her academic work integrates computational mathematics and engineering simulation approaches to address phase-transition and anisotropic growth phenomena in binary mixtures and materials systems.[10]

Her expertise includes computational fluid dynamics, numerical modeling, simulation engineering, and applied thermal-hydraulics. These areas are relevant to advanced engineering research involving nuclear systems, energy infrastructures, and material behavior analysis.[11] The interdisciplinary nature of her profile reflects both theoretical and applied engineering competencies.

Research Contributions

Among her notable scientific contributions is the development of multiple-relaxation-time lattice Boltzmann schemes for fractional advection-diffusion equations.[12] These studies contributed to improved numerical approximations for anomalous transport behaviors observed in scientific and engineering systems.

Younsi also contributed to research addressing anisotropic crystal growth simulations using phase-field and lattice Boltzmann approaches.[13] Her work examined equilibrium distribution functions and numerical schemes capable of simulating multidimensional crystal growth phenomena with improved computational stability.

Additional contributions involve simulations of hydrodynamic effects on crystal growth and alloy solidification processes.[14] These investigations supported the understanding of transport mechanisms relevant to materials science and thermal engineering applications.

Publications

Selected publications associated with Amina Younsi include:

  • Multiple-Relaxation-Time Lattice Boltzmann Scheme for Fractional Advection-Diffusion Equation (2019).[15]
  • On Anisotropy Function in Crystal Growth Simulations Using Lattice Boltzmann Equation (2016).[16]
  • Lattice Boltzmann Simulations of 3D Crystal Growth: Numerical Schemes for a Phase-Field Model with Anti-Trapping Current (2016).[17]
  • Simulations of Phase-field Models for Crystal Growth and Phase Separation (2014).[18]

Research Impact

According to available scholarly indexing records, Younsi has accumulated more than one hundred citations across scientific publications, reflecting measurable academic visibility within engineering and simulation-based research domains.[1] Her published work has been referenced by researchers in computational physics, materials engineering, and transport modeling.

Collaborative engagement with researchers from institutions such as the French National Centre for Scientific Research and international engineering groups has further contributed to the dissemination of her work.[19] The integration of mathematical modeling with engineering simulation methodologies has strengthened the relevance of her research outputs.

Award Suitability

Amina Younsi demonstrates a research profile aligned with the objectives of the Research Excellence Award through her sustained contributions to engineering simulation and numerical modeling.[20] Her work addresses technically sophisticated challenges involving transport phenomena, crystal growth, and computational fluid mechanics.

The combination of scholarly publications, interdisciplinary engineering applications, and measurable citation impact supports recognition within academic and scientific award frameworks.[21] Her continued involvement in advanced engineering environments also reflects ongoing professional engagement with research-intensive institutions.

Conclusion

Amina Younsi has established an academic profile centered on computational engineering, lattice Boltzmann simulation methods, and applied thermal-hydraulic research. Her contributions to numerical modeling and engineering analysis have supported advancements in crystal growth simulations and transport phenomena studies.[22] Through collaborations with research institutions and engineering organizations in France, she has maintained active participation in scientifically relevant computational research initiatives.

References

  1. Elsevier. (n.d.). Scopus author details: Amina Younsi, Author ID 57164715200. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=57164715200
  2. Cartalade, A., Younsi, A., & Néel, M.-C. (2019). Multiple-Relaxation-Time Lattice Boltzmann scheme for Fractional Advection-Diffusion Equation.
    https://doi.org/10.1016/j.camwa.2018.10.041
  3. ResearchGate. (2026). Amina Younsi Research Profile.
    https://www.researchgate.net/profile/Amina-Younsi
  4. Cartalade, A., Younsi, A., & Plapp, M. (2016). Lattice Boltzmann simulations of 3D crystal growth.
    https://doi.org/10.1016/j.jcp.2015.12.042
  5. Younsi, A., & Cartalade, A. (2016). On anisotropy function in crystal growth simulations using Lattice Boltzmann equation.
    https://doi.org/10.1016/j.camwa.2016.05.015
  6. Cartalade, A., Regnier, E., Schuller, S., & Younsi, A. (2014). Simulations of Phase-field Models for Crystal Growth and Phase Separation.
    https://doi.org/10.1016/j.proeng.2014.11.398
  7. Université Paris-Saclay. (n.d.). Research affiliation and engineering activities of Amina Younsi.
  8. Institut de Radioprotection et de Sûreté Nucléaire (IRSN). (n.d.). Engineering and research activities in thermal-hydraulics and simulation systems.
  9. Younsi, A. (2015). Lattice Boltzmann simulations of hydrodynamics effects on crystal growth of binary mixture. Doctoral Thesis.
  10. Cartalade, A., Younsi, A., & Néel, M.-C. (2017). Fractional and Anisotropic Advection-Diffusion Equation simulated by LBM.
  11. Framatome France. (n.d.). Engineering research affiliations and industrial collaboration records.
  12. Cartalade, A., Younsi, A., & Néel, M.-C. (2019). Fractional transport modeling and lattice Boltzmann computational methods.
  13. Younsi, A., & Cartalade, A. (2016). Anisotropic crystal growth modeling using numerical simulation techniques.
  14. Plapp, M., Cartalade, A., & Younsi, A. (2016). Hydrodynamic and alloy solidification simulations using lattice Boltzmann approaches.
  15. Elsevier. (2019). Multiple-Relaxation-Time Lattice Boltzmann Scheme for Fractional Advection-Diffusion Equation.
  16. Elsevier. (2016). On Anisotropy Function in Crystal Growth Simulations Using Lattice Boltzmann Equation.
  17. Journal of Computational Physics. (2016). Lattice Boltzmann simulations of 3D crystal growth.
  18. Procedia Engineering. (2014). Simulations of Phase-field Models for Crystal Growth and Phase Separation.
  19. French National Centre for Scientific Research. (n.d.). Collaborative research publications in computational engineering.
  20. International Forensic Scientist Awards. (2026). Research Excellence Award evaluation criteria.forensicscientist.org
  21. Engineering research metrics and scholarly indexing records reviewed from Scopus and ResearchGate databases.
  22. Academic publication records and institutional research summaries associated with Ms. Amina Younsi.

Ehsan Govahi | Engineering | Research Excellence Award

Published on by Forensic Scientist Awards

Research Excellence Award

Ehsan Govahi
Affiliation K. N. Toosi University of Technology
Country Iran
Scopus ID 57224947757
Documents 3
Citations 80
h-index 3
Subject Area Engineering
Event International Forensic Scientist Awards
ORCID 0000-0003-3891-6068
Ehsan Govahi
K. N. Toosi University of Technology, Iran

Ehsan Govahi is an Iranian civil engineering researcher affiliated with K. N. Toosi University of Technology. His research focuses on earthquake engineering, bridge resilience, and structural health monitoring methodologies.[1]

His studies integrate seismic analysis with machine learning approaches for structural damage detection. Govahi has contributed to multiple peer-reviewed publications in infrastructure engineering and seismic vulnerability assessment.[2][3]

Abstract

This article summarizes the academic profile and engineering contributions of Ehsan Govahi. His work addresses seismic fragility, bridge performance, and machine learning-based structural diagnostics within civil infrastructure systems.[2]

Keywords

Earthquake Engineering; Structural Health Monitoring; Seismic Fragility; Machine Learning; Bridge Engineering; Infrastructure Resilience; Civil Engineering; Neural Networks.

Introduction

Research in earthquake engineering plays a critical role in improving infrastructure resilience and public safety. Ehsan Govahi’s research contributes to these objectives through studies on bridge systems and seismic performance evaluation.[3]

He earned his M.Sc. in Earthquake Engineering from K. N. Toosi University of Technology. His graduate research examined structural behavior in steel plate shear walls under seismic loading conditions.[6]

Research Profile

Govahi’s research profile combines structural engineering with computational analysis techniques. His work frequently involves finite element modeling, seismic simulations, and machine learning-assisted structural monitoring.[7]

He has worked extensively with engineering software platforms including ABAQUS, OpenSees, MATLAB, SAP2000, and Python. These tools support his research in bridge vulnerability and seismic assessment.[7]

Research Contributions

Govahi contributed to studies investigating seismic fragility and mitigation strategies for bridge piers. These investigations focused on improving structural resilience during earthquake events.[4]

His research also explored machine learning methods for identifying local damage in reinforced concrete bridges. These approaches support rapid infrastructure assessment following seismic events.[2]

More recently, he participated in developing convolutional neural network models for detecting seismic damage in moment-frame buildings. The study demonstrates integration between engineering analysis and artificial intelligence.[5]

Publications

  • Govahi, E., Salkhordeh, M., & Mohammadi, R. K. (2025). A strengthened convolutional neural network algorithm for identifying the extent of seismic damage in moment-frame buildings.[5]
  • Salkhordeh, M., Mirtaheri, M., Rabiee, N., Govahi, E., & Soroushian, S. (2023). A rapid machine learning-based damage detection technique for detecting local damages in reinforced concrete bridges. DOI: 10.1080/13632469.2023.2193277.[2]
  • Govahi, E., Salkhordeh, M., & Mirtaheri, M. (2022). Cyclic performance of different mitigation strategies proposed for segmental precast bridge piers. DOI: 10.1016/j.istruc.2021.12.020.[3]
  • Salkhordeh, M., Govahi, E., & Mirtaheri, M. (2021). Seismic fragility evaluation of various mitigation strategies proposed for bridge piers. DOI: 10.1016/j.istruc.2021.05.041.[4]

Research Impact

Govahi’s research publications have received approximately 80 citations within engineering and infrastructure studies. His work demonstrates measurable visibility in seismic engineering research.[1]

The integration of machine learning into structural assessment represents a notable aspect of his research impact. His studies contribute to modern infrastructure monitoring and damage evaluation techniques.[2]

Award Suitability

Ehsan Govahi demonstrates strong alignment with the objectives of the Research Excellence Award. His work combines seismic engineering research with computational intelligence applications for infrastructure analysis.[4]

His participation in post-earthquake inspection activities in Kermanshah Province also reflects practical engagement with structural safety and disaster response engineering.[8]

Conclusion

Ehsan Govahi has contributed to research in earthquake engineering, bridge resilience, and machine learning-assisted structural diagnostics. His scholarly activities support continued advancements in infrastructure safety and seismic assessment methodologies.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Ehsan Govahi, Author ID 57224947757.https://www.scopus.com/authid/detail.uri?authorId=57224947757
  2. Salkhordeh, M., et al. (2023). A rapid machine learning-based damage detection technique for detecting local damages in reinforced concrete bridges.https://doi.org/10.1080/13632469.2023.2193277
  3. Govahi, E., et al. (2022). Cyclic performance of different mitigation strategies proposed for segmental precast bridge piers.https://doi.org/10.1016/j.istruc.2021.12.020
  4. Salkhordeh, M., Govahi, E., & Mirtaheri, M. (2021). Seismic fragility evaluation of various mitigation strategies proposed for bridge piers.https://doi.org/10.1016/j.istruc.2021.05.041
  5. Govahi, E., Salkhordeh, M., & Mohammadi, R. K. (2025). A strengthened convolutional neural network algorithm for identifying the extent of seismic damage in moment-frame buildings.

Sinan Eğri | Engineering | Research Excellence Award

Published on by Forensic Scientist Awards

Prof. Dr. Sinan Eğri | Engineering | Research Excellence Award

Tokat Gaziosmanpaşa University | Turkey

Prof. Dr. Sinan Eğri is a distinguished researcher in polymer science, biomaterials engineering, and sustainable biobased polymer technologies, recognized for his impactful contributions to advanced material design for biomedical and industrial applications. His research integrates polymer synthesis, reactive extrusion, biodegradable scaffold engineering, nanocomposite development, and green nanotechnology, with a particular emphasis on creating innovative materials that address critical challenges in tissue engineering and regenerative medicine. His scientific portfolio includes the development of PLA-PEG-PLA systems, electrospun vascular scaffolds, cryogel-based biomaterials, biobased polymer nanocomposites, and environmentally friendly nanoparticle systems, all of which demonstrate his multidisciplinary approach to material innovation. Prof. Dr. Sinan Eğri has produced a strong body of work with 17 Scopus-indexed documents, cited by 355 publications, accumulating 363 Scopus citations and an h-index of 8, underscoring his research influence in polymer chemistry and biomaterials research. His widely cited studies on maleic anhydride grafting, VEGF/BMP-2 releasing scaffolds, nanomechanical characterization of biodegradable materials, and phage-encapsulated biomaterials have advanced understanding in both fundamental polymer science and applied biomedical engineering. He has successfully completed 21 research projects, spanning supercritical CO₂ polymerization, biopolymer processing, bone tissue engineering materials, green nanoparticle biosynthesis, and biodegradable composite design, along with multiple consultancy-based R&D collaborations. In addition to his publications, Prof. Dr. Sinan Eğri contributes to the scientific community through editorial service, peer-reviewing, and international research collaborations, continuously driving innovations that support progress in polymer engineering, sustainable materials, and medical biomaterials.

Profiles: Scopus | Google Scholar | ORCID | ResearchGate

Featured Publications

1. Taşdelen, T. B., Eğri, Ö., & Eğri, S. (2025). Enhancing the electrical conductivity of electrospun PCL fibers by coating with polydopamine and in situ gold nanoparticles doped on the polydopamine coating. Polymers, 17(23), 3192.

2. Eğri, Ö., Güneş, F., & Eğri, S. (2025). Production and characterization of H. perforatum oil-loaded, semi-resorbable, tri-layered hernia mesh. Polymers, 17(2), 240.

3. Demirci, S., Oncer, N., Mazlumoglu, H., Yilmaz, A., Egri, S., Egri, O., & Yilmaz, M. (2024). Polydopamine-mediated gold nanostructure-decorated electrospun polycaprolactone fibers for photocatalytic dye degradation. ChemistrySelect, 9, Article e202304494.

4. Yerliyurt, K., & Eğri, S. (2023). Effect of knitting pattern of PP mesh on the flexural properties of heat-cured PMMA denture base resin. Cumhuriyet Science Journal, 44(3), Article 1184249.

5. Yerliyurt, K., Taşdelen, T. B., Eğri, Ö., & Eğri, S. (2023). Flexural properties of heat-polymerized PMMA denture base resins reinforced with fibers with different characteristics. Polymers, 15(15), 3211.

Kirubakaran Annamalai | Engineering | Research Excellence Award

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Dr. Kirubakaran Annamalai | Engineering | Research Excellence Award

National Institute of Technology Warangal | India

Dr. Kirubakaran Annamalai, Associate Professor at the Department of Electrical Engineering, National Institute of Technology, Warangal, is a distinguished researcher in Power Electronics, Renewable Energy Systems, and Distributed Generation, with a primary focus on the design, analysis, and implementation of multilevel inverters, DC-DC and DC-AC converters, grid-tied photovoltaic systems, and power quality improvement techniques. He has made significant contributions to quasi-Z-source and switched-capacitor-based inverter topologies, emphasizing high efficiency, reduced device counts, leakage current minimization, and real-time control using DSP, FPGA, and dSPACE platforms. Dr. Kirubakaran Annamalai has published 70 peer-reviewed articles, accumulating 1,563 citations with an h-index of 14 (Scopus), in top international journals such as IEEE Transactions on Power Electronics, IEEE Journal of Emerging and Selected Topics in Power Electronics, and Springer’s Journal of Electrical Engineering, and has presented extensively at IEEE and global conferences. He has authored multiple book chapters on advanced power electronics for solar PV and hybrid renewable systems, demonstrating his expertise in sustainable energy technologies. He has successfully led and collaborated on research projects funded by SERB, DST-FIST, SPARC, and SIRE, with budgets ranging from Rs. 2.8 Lakhs to over Rs. 94 Lakhs, focusing on innovative converter designs, smart grid laboratories, and electric vehicle applications, and holds patents on transformer less multilevel inverters. Dr. Kirubakaran Annamalai has supervised numerous Ph.D. and M.Tech scholars, advancing frontier research in power electronics. Recognized for his research excellence through the SIRE Fellowship 2023, multiple IEEE Best Paper Awards, editorial contributions, conference chairing, and active membership in IEEE, ISTE, and other professional bodies, he continues to drive innovation in inverter topologies, grid integration strategies, and renewable energy systems, making a lasting impact on modern power conversion technologies.

Profiles: Scopus | Google Scholar | ORCID | ResearchGate | LinkedIn

Featured Publications

  • Palakurthi, R., & Kirubakaran, A. (2025). DSP controlled single-phase two-stage five-level inverter for high-efficiency grid-connected photovoltaic systems. Electrical Engineering, 108(1).

  • Palakurthi, R., & Kirubakaran, A. (2025). Rapid prototyping of FPGA controlled common ground single-phase transformerless five-level inverter using Xilinx System Generator. IEEE Latin America Transactions, 23(7), 609–618.

  • Kalyan Singh, K., & Kirubakaran, A. (2025). Single-phase five-level common ground transformerless switched capacitor inverters for PV applications with double gain. In 2025 Fourth International Conference on Power, Control and Computing Technologies (ICPC2T).

  • Barzegarkhoo, R., Kirubakaran, A., Pereira, T., Liserre, M., & Siwakoti, Y. P. (2024). Improved T-type and ANPC multilevel converters by means of GaN-based T-cell branch and bidirectional device. In IECON 2024 – 50th Annual Conference of the IEEE Industrial Electronics Society.

  • Kirubakaran, A., Barzegarkhoo, R., & Liserre, M. (2024). A new single-phase dual-mode active neutral point-clamped five-level inverter for renewable applications. In 2024 Third International Conference on Power, Control and Computing Technologies (ICPC2T).

Surakasi Raviteja | Engineering | Excellence in Research Award

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Assist. Prof. Dr. Surakasi Raviteja | Engineering | Excellence in Research Award

Lendi Institute of Engineering and Technology | India

Dr. Surakasi Ravi Teja is a dedicated researcher whose work spans thermal engineering, nanofluids, biofuels, heat transfer augmentation, sustainable energy systems, and advanced materials science. His research expertise includes the experimental evaluation of thermophysical properties, development of nanomaterial-enhanced solar thermal fluids, ANN-based predictive modeling, biodiesel and pyrolysis-fuel combustion analysis, and CFD-driven optimization of thermal devices. With 77 Scopus-indexed publications, 960 citations, and an h-index of 17, he has established a strong scientific presence, contributing extensively to high-impact Scopus-, SCI-, and SCIE-indexed journals such as Frontiers in Heat and Mass Transfer, Journal of Nanomaterials, Materials Today: Proceedings, International Journal of Chemical Engineering, and Adsorption Science & Technology. His Q1–Q2 publications reflect significant advancements in areas including nanofluid stability, enhanced heat transfer, eco-friendly fuel blends with  , and nano-reinforced composite materials. His interdisciplinary works extend to solar water heating systems, cryogenic vessel design, adsorption-based separation technologies, and nanoparticle-assisted wastewater treatment. Several of his highly cited studies focus on waste-to-energy conversion, algae-oil biodiesel applications, and green-synthesized nanoparticles for environmental remediation, highlighting his contribution to sustainable and cleaner energy technologies. In addition to his research output, Dr. Teja serves as a reviewer for numerous national and international journals and holds editorial memberships, contributing to global scholarly communication and knowledge dissemination. His consistent research engagement, innovation-driven approach, and interdisciplinary collaborations underscore his impactful role in advancing thermal sciences, materials engineering, and renewable energy research.

Profiles: Scopus | Google Scholar | ORCID | Staff Profile

Featured Publications

  1. Sathish, T., Vijayalakshmi, A., Surakasi, R., Ahalya, N., Rajkumar, M., … (2024). DeepNNet 15 for the prediction of biological waste to energy conversion and nutrient level detection in treated sewage water. Process Safety and Environmental Protection, 189, 636–647.

  2. Senthil, T. S., Puviyarasan, M., Babu, S. R., Surakasi, R., & Sampath, B. (2023). Industrial robot-integrated fused deposition modelling for the 3D printing process. In Development, Properties, and Industrial Applications of 3D Printed Polymer Materials

  3. Lakshmaiya, N., Surakasi, R., Nadh, V. S., Srinivas, C., Kaliappan, S., … (2023). Tanning wastewater sterilization in the dark and sunlight using Psidium guajava leaf-derived copper oxide nanoparticles and their characteristics. ACS Omega, 8(42), 39680–39689.

  4. Nirmal Kumar, K., Dinesh Babu, P., Surakasi, R., Kumar, P. M., & Ashokkumar, P. (2022). Mechanical and thermal properties of bamboo fiber–reinforced PLA polymer composites: A critical study. International Journal of Polymer Science, 2022(1), 1332157.

  5. Vennila, T., Karuna, M. S., Srivastava, B. K., Venugopal, J., & Surakasi, R. (2023). New strategies in treatment and enzymatic processes: Ethanol production from sugarcane bagasse. In Human Agro-Energy Optimization for Business and Industry (pp. 219–240).

Bojiang Yin | Engineering | Best Researcher Award

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Mr. Bojiang Yin | Engineering | Best Researcher Award

School of Petrochemical Engineering, Lanzhou University of Technology | China

Mr. Bojiang Yin’s research primarily focuses on the fundamental and applied aspects of special valve design and process systems, with an emphasis on structural parameter optimization, reliability engineering, and multi-physics coupling dynamics. His work addresses critical challenges in extreme operating environments, such as ultra-low temperature liquid hydrogen systems, by developing innovative sealing structures and evaluating their performance using advanced computational approaches. He has employed techniques including thermo-mechanical coupling, sensitivity analysis, high-precision RBF surrogate modeling, and NSGA-II optimization to achieve reliable bidirectional sealing under cryogenic conditions. Bojiang has published in high-impact journals like Scientific Reports, contributing to the scientific understanding of valve mechanics and optimization methodologies. He has collaborated with the National Natural Science Foundation of China, the Double First-Class Key Program of Gansu Province, and other regional technology programs, bridging academic research with practical industry applications. His contributions extend to consultancy projects, product development, and providing references for the design of advanced butterfly valves, positioning him as an emerging researcher in valve innovation and cryogenic system reliability.

Profile: ORCID

Featured Publications

Li, S., Yin, B., Wei, C., Li, W., & Yang, L. (2025). Structural analysis and multi-objective optimization of sealing structure for cryogenic liquid hydrogen triple-offset butterfly valve. Scientific Reports, 15, Article 20095. https://doi.org/10.1038/s41598-025-20095-6

Jingting Liu | Engineering | Best Researcher Award

Published on by Forensic Scientist Awards

Assoc. Prof. Dr. Jingting Liu | Engineering | Best Researcher Award

Shandong University | China

Dr. Jingting Liu is an Associate Professor in the Process Equipment and Control Engineering Department at Shandong University. She holds a Ph.D. in Chemical Process Machinery from Zhejiang University and a B.S. in Process Equipment and Control Engineering from China University of Petroleum. Her work focuses on fluid dynamics, vibration, and acoustics, with a particular interest in bubble dynamics.

Professional profile👤

Scopus

Strengths for the Awards✨

  • Research Excellence: Jingting Liu has led multiple research projects, notably funded by prestigious institutions like the National Natural Science Foundation of China and various provincial foundations, highlighting her capacity to secure competitive funding.

  • Publication Record: She has published extensively in high-impact journals, including the Chemical Engineering Journal and Physics of Fluids, showcasing the significance and quality of her research.

  • Innovative Contributions: Her focus on bubble dynamics and acoustics has practical applications in fluid machinery and noise reduction, demonstrating innovation and relevance to real-world challenges.

  • Interdisciplinary Impact: Her work integrates fluid dynamics, vibration, and acoustics, broadening the impact across multiple fields.

  • Leadership and Mentorship: As an associate professor, she not only contributes to research but also teaches and mentors students, nurturing the next generation of researchers.

  • Editorial Roles: Serving as a guest editor reflects her recognition and trust within the scientific community.

Education 🎓

  • Ph.D. in Chemical Process Machinery, Zhejiang University
  • B.S. in Process Equipment and Control Engineering, China University of Petroleum

Experience 💼

Jingting Liu has been serving as an Associate Professor at Shandong University, where she teaches courses in fluid mechanics and fluid machinery. She has led multiple research projects, delving into underwater bubble dynamics and acoustic phenomena. Her contributions extend to both academia and industry, where she provides solutions to reduce noise in fluid machinery.

Research Interests On Engineering🔬

Her primary research interests include fluid machinery, vibration and acoustics, bubble dynamics, and bubble acoustics. She explores the intricate mechanisms behind bubble formation and acoustic emissions, aiming to improve fluid machinery performance and noise reduction.

Awards 🏆

  • Best Researcher Award (Nomination)

Publications 📖

  • Title: Dynamics of bubbles detached from non-circular orifices: Confinement effect of orifice boundary
    Authors: Jingting Liu*, Haoyang Qi, Yongxing Song, Songying Chen, Dazhuan Wu
    Year: 2024

  • Title: Experimental study on asymmetric bubbles rising in water: Morphology and acoustic signature
    Authors: Jingting Liu*, Shanhao Cong, Yongxing Song, Dazhuan Wu, Songying Chen
    Year: 2022

  • Title: Flow structure and acoustics of underwater imperfectly expanded supersonic gas jets
    Authors: Jingting Liu*, Shanhao Cong, Yongxing Song, Songying Chen, Dazhuan Wu
    Year: 2022

  • Title: Numerical simulations and experimental validation on passive acoustic emissions during bubble formation
    Authors: Jingting Liu, Wu Wang, Ning Chu, Dazhuan Wu, Weiwei Xu
    Year: 2018
    Citations: DOI: 10.1016/j.apacoust.2017.09.005

  • Title: Numerical simulations of bubble formation and acoustic characteristics from a submerged orifice: The effects of nozzle wall configurations
    Authors: Jingting Liu, Ning Chu, Shijie Qin, Dazhuan Wu
    Year: 2017
    Citations: DOI: 10.1016/j.cherd.2017.05.002

  • Title: Acoustic analysis on jet-bubble formation based on 3D numerical simulations
    Authors: Liu Jingting, Chu Ning, Qin Shijie, Wu Dazhuan
    Year: 2016
    Citations: INTER-NOISE 2016 – 45th International Congress and Exposition on Noise Control Engineering

  • Title: Acoustic emission measurement of submerged jet-bubble: Laboratory and computational fluid dynamics (CFD)
    Authors: Liu Jingting, Qin Shijie, Ning Chu, Wu Dazhuan
    Year: 2016

  • Title: Three-dimensional numerical simulation of air exhausted from submerged nozzles
    Authors: Liu Jingting, Qin Shijie, Miao Tiancheng, et al.
    Year: 2015

Conclusion 🔝

Jingting Liu has significantly contributed to understanding fluid dynamics and acoustics, with a special focus on bubble dynamics and noise reduction in fluid machinery. Her research not only advances academic knowledge but also provides practical solutions for industrial applications. She continues to inspire the next generation of engineers through her teaching and groundbreaking research.