Dr. Ehsan Adibnia | Photonics | Best Researcher Award

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Dr. Ehsan Adibnia | Photonics | Best Researcher Award

Researcher | University of Sistan and Baluchestan | Iran

Dr. Ehsan Adibnia is a distinguished researcher in electrical engineering whose work exemplifies excellence in the integration of artificial intelligence and photonics. With a citation count of 6,447, an h-index of 45, and an i10-index of 153, his contributions to nanophotonics, plasmonics, and photonics-based optical communication have gained wide recognition. His research explores deep learning applications in photonic design, optical switching, and plasmonic structures, emphasizing the transformative role of photonics in next-generation computing and biosensing technologies. Dr. Adibnia has served as an assistant editor and reviewer for several high-impact journals, contributing to the advancement of global photonics research. His professional experience combines academic rigor and industrial insight, including expertise in programming, simulation tools like Lumerical and COMSOL, and PLC automation. His educational foundation in electrical engineering and his scholarly engagement at the University of Sistan and Baluchestan have provided a platform for innovative exploration in nanophotonics, quantum photonics, and integrated photonic circuits. Recognized for his excellence in photonics-driven design optimization, he has published influential studies on inverse design methods for fiber Bragg gratings, plasmonic resonators, and photonic crystal devices. His research interests span from artificial-intelligence-enhanced photonic structures to optical biosensors and metamaterials, underlining his commitment to interdisciplinary innovation. Through awards, editorial service, and sustained academic leadership, Dr. Adibnia continues to shape the evolving landscape of photonics, positioning his work at the intersection of computation, materials science, and optical engineering, where photonics defines the future of high-speed, intelligent systems.

Profiles: ORCID | Google Scholar

Featured Publications

1. Mirbagheri, M., Adib, E., Hughes, B. R., Waldman, S. D., Banquy, X., & Hwang, D. K. (2019). Advanced cell culture platforms: A growing quest for emulating natural tissues. Materials Horizons, 6(1), 45–71.

2. Esteki, M., Poorali, B., Adib, E., & Farzanehfard, H. (2015). Interleaved buck converter with continuous input current, extremely low output current ripple, low switching losses, and improved step-down conversion ratio. IEEE Transactions on Industrial Electronics, 62(8), 4769–4776.

3. Bahrami, H., Farhangi, S., Iman-Eini, H., & Adib, E. (2017). A new interleaved coupled-inductor nonisolated soft-switching bidirectional DC–DC converter with high voltage gain ratio. IEEE Transactions on Industrial Electronics, 65(7), 5529–5538.

4. Adib, E., & Farzanehfard, H. (2008). Family of zero-current transition PWM converters. IEEE Transactions on Industrial Electronics, 55(8), 3055–3063.

5. Adib, E., & Farzanehfard, H. (2009). Zero-voltage transition current-fed full-bridge PWM converter. IEEE Transactions on Power Electronics, 24(4), 1041–1047.*

Dr. Wu Qiuxuan | Robotics and Automation | Best Researcher Award

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Dr. Wu Qiuxuan | Robotics and Automation | Best Researcher Award

Teacher | Hangzhou Dianzi university | China

Dr. Wu Qiuxuan, an Associate Professor at the School of Automation, Hangzhou Dianzi University, is a distinguished researcher whose expertise and leadership have significantly advanced the field of Robotics and Automation. With a Ph.D. in Control Science and Engineering from Shanghai Jiaotong University, his academic journey reflects a deep commitment to innovation in Robotics and Automation, particularly in the areas of soft robotics, evolutionary learning, and home energy systems. Dr. Wu’s professional experience includes academic and research roles, notably as a visiting scholar at the Australian National University, where he furthered his understanding of intelligent robotic systems. His extensive research on bipedal robots, underwater biomimetic designs, and bio-inspired control algorithms has earned him international recognition. Dr. Wu has authored impactful papers in leading journals such as IEEE Robotics and Automation Letters and Bioinspiration & Biomimetics, contributing to global advancements in Robotics and Automation. His work integrates advanced modeling, deep reinforcement learning, and optimization techniques to enhance robotic adaptability and performance. Over the years, Dr. Wu has received numerous research grants supporting his pioneering studies on service robots, industrial automation, and 3D bioprinting technologies, underscoring his central role in the evolution of Robotics and Automation. With 721 citations, an h-index of 11, and an i10-index of 20, his scholarly influence continues to grow. Dr. Wu’s research skills encompass algorithmic innovation, system optimization, and control engineering, blending theoretical insight with practical application. In conclusion, Dr. Wu Qiuxuan stands as a driving force in Robotics and Automation, whose interdisciplinary expertise continues to shape intelligent systems and inspire the next generation of automation research worldwide.

Profiles: ORCID | Google Scholar

Featured Publications

1. Cai, N., He, M., Wu, Q., & Khan, M. J. (2019). On almost controllability of dynamical complex networks with noises. Journal of Systems Science and Complexity, 32(4), 1125–1139.

2. Chi, X., Liu, B., Niu, Q., & Wu, Q. (2012). Web load balance and cache optimization design based nginx under high-concurrency environment. Proceedings of the Third International Conference on Digital Manufacturing & Automation, 69–73.

3. Wu, Q., Yang, X., Wu, Y., Zhou, Z., Wang, J., Zhang, B., Luo, Y., Chepinskiy, S. A., ... (2021). A novel underwater bipedal walking soft robot bio-inspired by the coconut octopus. Bioinspiration & Biomimetics, 16(4), 046007.

4. Wu, Q., Gu, Y., Li, Y., Zhang, B., Chepinskiy, S. A., Wang, J., Zhilenkov, A. A., ... (2020). Position control of cable-driven robotic soft arm based on deep reinforcement learning. Information, 11(6), 310.

5. Chi, X., Wang, C., Wu, Q., Yang, J., Lin, W., Zeng, P., Li, H., & Shao, M. (2023). A ripple suppression of sensorless FOC of PMSM electrical drive system based on MRAS. Results in Engineering, 20, 101427.

Dr. Temitope Adefarati | Engineering | Best Researcher Award

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Dr. Temitope Adefarati | Engineering | Best Researcher Award

Post Doctoral Fellowship | University of Johannesburg | South Africa

Dr. Temitope Adefarati is a distinguished Engineering scholar whose expertise in Electrical and Electronic Engineering has made notable contributions to renewable energy, power systems, and smart grid technology. He holds advanced Engineering degrees from prestigious universities, including a Ph.D. in Electrical Engineering, and has accumulated extensive experience in Engineering education, research, and industry. As an Engineering academic and researcher, he has served as an Associate Professor and Postdoctoral Fellow, contributing to Engineering curriculum development and the supervision of numerous postgraduate Engineering theses. His Engineering research focuses on optimizing renewable energy systems, distributed power generation, and sustainable energy integration. Dr. Adefarati’s Engineering excellence has been recognized through inclusion in the World’s Top 2% Scientists list for consecutive years and through his active role as an editorial board member of leading Engineering journals such as Frontiers in Smart Grids and International Journal of Energy Research. His Engineering research skills encompass power system reliability analysis, grid-connected PV optimization, and hybrid energy system simulation. With a prolific Engineering publication record in top-tier journals like Applied Energy, he has advanced the understanding of energy management and sustainable power systems. Dr. Adefarati’s Engineering commitment extends beyond academia through consultancy and professional affiliations, including COREN and the South African Institute of Electrical Engineers. His Engineering career demonstrates innovation, leadership, and dedication to advancing global energy solutions. Google Scholar profile of 2885 Citations, 31 i10 index, 22 h-index.

Profiles: ORCID | Google Scholar

Featured Publications

1. Adefarati, T., & Bansal, R. C. (2016). Integration of renewable distributed generators into the distribution system: A review. IET Renewable Power Generation, 10(7), 873–884.

2. Adefarati, T., & Bansal, R. C. (2019). Reliability, economic and environmental analysis of a microgrid system in the presence of renewable energy resources. Applied Energy, 236, 1089–1114.

3. Adefarati, T., & Bansal, R. C. (2017). Reliability assessment of distribution system with the integration of renewable distributed generation. Applied Energy, 185, 158–171.

4. Adefarati, T., & Bansal, R. C. (2017). Reliability and economic assessment of a microgrid power system with the integration of renewable energy resources. Applied Energy, 206, 911–933.

5. Adefarati, T., Bansal, R. C., & Just, J. J. (2017). Reliability and economic evaluation of a microgrid power system. Energy Proceedings, 142, 43–48.

Otilia Pitulac | Engineering | Best Researcher Award

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Ms. Otilia Pitulac | Engineering | Best Researcher Award

Teaching Assistant | Technical University Gheorghe Asachi Iasi | Romania

Ms. Otilia Pitulac is an emerging scholar in the field of Environmental Engineering, recognized for her growing expertise and dedication to sustainability-driven Engineering innovations. She currently serves as a Teaching Assistant at the “Gheorghe Asachi” Technical University of Iași, where she contributes to academic and research excellence in hydrotechnics, geodesy, and environmental Engineering. Her academic journey includes a PhD in Environmental Engineering, a Master’s in Geomatics and Cartography, and a Bachelor’s in Geography, reflecting a strong foundation in both theoretical and applied Engineering disciplines. Ms. Pitulac’s research interests lie in environmental management, green city development, climate resilience, and sustainable Engineering practices. Her work emphasizes innovative approaches to soil conservation, resource optimization, and urban ecological balance within modern Engineering systems. Throughout her academic and professional experience, she has demonstrated Engineering skills in GIS analysis, project coordination, sustainable soil management, and environmental modeling. Her Engineering achievements are complemented by strong teamwork and communication abilities, essential for collaborative research environments. Ms. Pitulac has been actively engaged in guiding students and supporting Engineering research projects focused on sustainability and urban innovation. She has shown excellence in applying Engineering principles to address real-world environmental challenges, contributing meaningfully to the field’s evolution. Through continuous learning, practical engagement, and technical proficiency, Ms. Otilia Pitulac exemplifies the new generation of researchers shaping the future of sustainable Engineering, demonstrating an unwavering commitment to innovation, academic integrity, and interdisciplinary advancement.

Profile: ORCID

Featured Publication

1. Pitulac, O., Chirilă, C., Stătescu, F., & Marcoie, N. (2025). GIS-based assessment of photovoltaic and green roof potential in Iași, Romania. Applied Sciences, 15(19), 10786.

Dr. Manda Malekpour | Higgs Physics | Best Researcher Award

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Dr. Manda Malekpour | Higgs Physics | Best Researcher Award

Researcher | University of Mazandaran | Iran

 Dr. Manda Malekpour is a distinguished physicist specializing in gravity, cosmology, and Higgs Physics, whose academic journey through advanced studies in cosmological inflation and gravitational theory demonstrates exceptional research depth. Her scholarly focus intertwines Higgs Physics with unimodular gravity, emphasizing the theoretical framework connecting cosmic inflation and the Higgs field. Through her doctoral and master’s research, she explored nonminimal unimodular cosmological inflation and the spectral properties of gravitational waves, integrating Higgs Physics concepts into cosmological models. Her publication record, including studies on Higgs inflation in unimodular gravity and ongoing research on reheating after Higgs inflation, highlights her continuing contribution to Higgs Physics. Dr. Malekpour’s academic work reflects mastery in theoretical modeling, programming, and computational simulation relevant to Higgs Physics and early-universe dynamics. Her analytical strength and ability to merge Higgs Physics with quantum field approaches have earned her recognition and awards within academic circles. She possesses strong research skills in mathematical physics, cosmological perturbation theory, and data analysis using Python and Maple. Her work represents a vital link between gravity, cosmology, and Higgs Physics, contributing to the deeper understanding of universe formation mechanisms. Dr. Malekpour’s innovative approach to Higgs Physics continues to advance modern cosmology and inspire new theoretical pathways for studying the universe’s fundamental structure, marking her as a promising contributor to the global scientific community. Her Google Scholar Citations 5, h-index 2, i10 index 0,

Profile: Google Scholar

Featured Publications

1. Nozari, K., & Malekpour, M. (2024). Higgs inflation in unimodular gravity. Progress of Theoretical and Experimental Physics, 2024(6), 063E02.

2. Malekpour, M., Nozari, K., Rajabi, F., & Rashidi, N. (2024). Non-minimal unimodular inflation. Physics of the Dark Universe, 43, 101405.

3. Malekpour, M., & Nozari, K. (2025). Reheating after the Higgs inflation. Annals of Physics, 170244.

Sathya Arumugam Thirumalai | Computational Methods | Young Scientist Award

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Mr. Sathya Arumugam Thirumalai | Computational Methods | Young Scientist Award

Mr. Sathya Arumugam Thirumalai | Indian Institute of Technology Roorkee | India

Mr. Sathya Arumugam Thirumalai is a highly motivated researcher whose work integrates Computational Methods with experimental nanomaterial science, emphasizing sustainability, environmental protection, and advanced detection technologies. His academic journey, from IIT Roorkee to TU Dresden, reflects an enduring commitment to merging experimental nanotechnology with Computational Methods for the synthesis and characterization of perovskite, MXene, and 2D materials. Mr. Sathya’s professional experience spans renowned institutions like IISc Bengaluru, BARC Mumbai, and IIT Roorkee, where he utilized Computational Methods in density functional theory (DFT) simulations, material modeling, and radiation detector design. His research, grounded in Computational Methods, has contributed to multiple journal publications addressing gas sensing, field emission, and radiation detection. He applies Computational Methods to optimize nanomaterial performance, enhance photonic properties, and improve the efficiency of radiation detectors. Recognized with several awards and fellowships, including the National Talent Search Fellowship and the Saxon Student Mobility Grant, he has demonstrated excellence in both theoretical and practical domains. His technical mastery extends to Python, MATLAB, COMSOL, and VASP, emphasizing his strength in applying Computational Methods across interdisciplinary fields. Mr. Sathya’s skill in Computational Methods enables him to bridge theoretical simulations with experimental validation, ensuring scientific precision and innovation. His collaborative engagements with global research groups highlight his leadership and cross-disciplinary adaptability. In conclusion, Mr. Sathya exemplifies how Computational Methods can revolutionize material science, fostering technological advancements that align with sustainability and human welfare.

Profiles: Google Scholar | ORCID

Featured Publications

1. Sathya, A. T., Jethawa, U., Sarkar, S. G., & Chakraborty, B. (2025). Pd-decorated MoSi₂N₄ monolayer: Enhanced nitrobenzene sensing through DFT perspective. Journal of Molecular Liquids, 427, 127310.

2. Sathya, A. T., Kandasamy, M., & Chakraborty, B. (2024). Strain induced nitrobenzene sensing performance of MoSi₂N₄ monolayer: Investigation from density functional theory. Surfaces and Interfaces, 55, 105386.

3. Sanyal, G., Vaidyanathan, A., Sathya, A. T., & Chakraborty, B. (2025). Efficient catechol sensing in newly synthesized 2D material Ti₂B MBene: Insights from density functional theory simulations. Langmuir, 41(33), 22525–22534.

4. Sathya, A. T., Sarkar, S. G., Bakhtsingh, R. I., & Mondal, J. (2024). Suppression of shielding effect of large area field emitter cathode in radio frequency gun environment. Physica Scripta, 99(12), 125301.

Dr. Jill P. Smith | Cancer therapeutics | Best Researcher Award

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Dr. Jill P. Smith | Cancer therapeutics | Best Researcher Award

Professor | Georgetown University | United States

Dr. Jill P. Smith is a distinguished Professor of Medicine at Georgetown University, holding dual appointments in the Departments of Medicine and Oncology, with leadership roles at the Lombardi Comprehensive Cancer Center. Her academic journey, from the University of Florida through the University of Missouri to her fellowship in Gastroenterology and Hepatology, has been marked by an enduring dedication to translational science and Cancer therapeutics. Over her illustrious career, Dr. Smith has pioneered landmark studies in Cancer therapeutics, particularly focusing on pancreatic and liver malignancies. Her investigations into cholecystokinin (CCK) receptor signaling, pancreatic tumor biology, and the development of proglumide-based interventions have advanced the understanding of Cancer therapeutics mechanisms at both cellular and systemic levels. She has directed numerous NIH and Department of Defense–funded projects that explore innovative Cancer therapeutics, such as receptor blockade, fibrosis modulation, and nanoparticle-based drug delivery systems. Dr. Smith’s honors include the Harrington Innovator Scholar Award, Bayer Discovery Awards, National Academy of Inventors membership, and Georgetown’s Innovator of the Year recognition—each underscoring her impact on Cancer therapeutics innovation. Her mentorship of generations of researchers and clinicians has fostered growth in translational research and Cancer therapeutics leadership. Her research skills encompass molecular oncology, preclinical modeling, pharmacological design, and clinical trial development in Cancer therapeutics, aligning scientific discovery with patient-centered outcomes. Dr. Smith’s professional excellence and lifelong pursuit of advancing Cancer therapeutics have made her a global authority in gastroenterological oncology. Scopus profile of 3,983 Citations, 109 Documents, 35 h-index.

Profile: Scopus

Featured Publications

1. Nature Communications. (2025). Allelic effects on KLHL17 expression underlie a pancreatic cancer genome-wide association signal at chr1p36.33.

2. Cancers. (2025). Mechanistic insights into proglumide’s role in immune cell efficacy and response to immune checkpoint inhibitor therapy in hepatocellular carcinoma.

3. Molecular Cancer Therapeutics. (2025). Target-specific locked nucleic acid gapmer decreases growth and metastases of pancreatic cancer.

4. Livers. (2025). Endogenous alcohol and auto-brewery syndrome complicating liver transplantation: A case report and literature review.

5. Cancer Investigation. (2025). A phase I study of the naturally occurring bioactive, opioid growth factor, in patients with unresectable hepatocellular cancer.

Prof. Viktor Mykhas’kiv | Computational Methods | Best Researcher Award

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Prof. Viktor Mykhas’kiv | Computational Methods | Best Researcher Award

Leading Scientific Researcher | Institute for Applied Problemss of Mechanics and Mathematics | Ukraine

Prof. Viktor Mykhas’kiv is a distinguished researcher at the Pidstryhach Institute for Applied Problems of Mechanics and Mathematics, National Academy of Sciences of Ukraine. His academic achievements include a Doctor of Science in Physics and Mathematics and a professorship in Mechanics of Deformable Solids. His extensive expertise in Computational Methods spans across Computational Mechanics, Materials Science, Structural Mechanics, and Multiscale Mathematical Modeling. Through his pioneering work, he has applied Computational Methods to study wave propagation, metamaterials, and nanomechanics, advancing knowledge in multiple scattering theory. His research leadership in international collaborations under INTAS, STCU, DAAD, DFG, and Fulbright programs highlights his ability to integrate Computational Methods within global scientific frameworks. As a team leader and project manager, he has promoted innovative Computational Methods in the investigation of elastic metamaterials and complex lattice structures. He has published widely, authoring over seventy-six Scopus-indexed papers, two books, and contributing to editorial boards of international journals like Mathematical Methods and Physicomechanical Fields. His commitment to excellence in Computational Methods is reflected in his role as a member of the European Structural Integrity Society. He has also served as a visiting researcher in the USA and Germany, applying Computational Methods to solve advanced mechanical and physical problems. His awards and honors recognize his groundbreaking use of Computational Methods in applied mechanics and theoretical modeling. With remarkable research skills and professional integrity, Prof. Viktor Mykhas’kiv continues to contribute significantly to global scientific progress. Scopus profile of 474 Citations, 76 Documents, 14 h-index.

Profiles: Scopus | ORCID

Featured Publications

1. Stankevych, V. Z., & Mykhas’kiv, V. V. (2023). Intensity of dynamic stresses of longitudinal shear in a periodically layered composite with penny-shaped cracks. Journal of Mathematical Sciences, 269(2), 268–280.

2. Mykhas’kiv, V. V., & Stasyuk, B. M. (2021). Effective elastic moduli of short-fiber composite with sliding contact conditions at interfaces. Mechanics of Composite Materials, 57(6), 845–854.

3. Mykhas’kiv, V., & Stankevych, V. (2019). Elastodynamic problem for a layered composite with penny-shaped crack under harmonic torsion. ZAMM – Zeitschrift für Angewandte Mathematik und Mechanik, 99(8), e201800193.

4. Mykhas’kiv, V. V., Zhbadynskyi, I. Y., & Zhang, C. (2019). On propagation of time-harmonic elastic waves through a double-periodic array of penny-shaped cracks. European Journal of Mechanics - A/Solids, 74, 68–77.

5. Zhbadynskyi, I. Y., & Mykhas’kiv, V. V. (2018). Acoustic filtering properties of 3D elastic metamaterials structured by crack-like inclusions. Proceedings of the International Seminar/Workshop on Direct and Inverse Problems of Electromagnetic and Acoustic Wave Theory (DIPED), 54–59.

Assist. Prof. Dr. Hassan Nasiri Mardanqom | Plasmonics | Best Researcher Award

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Assist. Prof. Dr. Hassan Nasiri Mardanqom | Plasmonics | Best Researcher Award

Postdoctoral Researcher | University of Tabriz | Iran

Assist. Prof. Dr. Hassan Nasiri Mardanqom is a distinguished researcher whose academic and professional endeavors are deeply rooted in the field of plasmonics, biophotonics, and nanoengineering. His extensive work as a postdoctoral researcher at the University of Tabriz in both Biochemistry and Electrical Engineering has positioned him at the forefront of plasmonics-based sensor technology. With advanced expertise in plasmonics, quantum technology, and nanocomposites, his research primarily revolves around the design and fabrication of plasmonics-enhanced optical and biosensing systems. Through innovative applications of plasmonics in biophotonic platforms, he has developed several highly sensitive surface plasmon resonance (SPR) sensors for detecting substances such as melamine, nitrite, and Amlodipine. His mastery in simulation software like COMSOL and Lumerical allows him to optimize plasmonics structures and their optical interactions at the nanoscale. Recognized for his achievements with top academic rankings and awards, Assist. Prof. Dr. Nasiri has authored numerous high-impact plasmonics publications in Q1 and Q2 journals. His laboratory experience encompasses advanced instrumentation, including cyclic voltammetry, flow cytometry, and plasmonics instruments such as Bionavis 210. Beyond technical proficiency, his contributions to teaching and mentoring reflect a deep commitment to advancing plasmonics and biophotonic research. Overall, his scientific vision emphasizes the integration of plasmonics in biomedical sensing and optical communication, highlighting his role as a pioneering force in next-generation plasmonics-driven nanotechnology.

Profile: Google Scholar

Featured Publications

1. Nasiri, H., Baghban, H., Teymouri-Mofrad, R., & Mokhtarzadeh, A. (2023). Graphitic carbon nitride/magnetic chitosan composite for rapid electrochemical detection of lactose. International Dairy Journal, 136, 105489.

2. Nasiri, H., & Abbasian, K. (2024). High-sensitive surface plasmon resonance sensor for melamine detection in dairy products based on graphene oxide/chitosan nanocomposite. Food Control, 166, 110761.

3. Nasiri, H., Abbasian, K., Salahandish, M., & Elyasi, S. N. (2024). Sensitive surface plasmon resonance biosensor by optimized carboxylate functionalized carbon nanotubes/chitosan for amlodipine detecting. Talanta, 276, 126249.

4. Nasiri, H., Abbasian, K., & Baghban, H. (2024). Highly sensitive quantification of amlodipine in real samples using graphene oxide-chitosan surface plasmon resonance sensor. Sensors and Actuators A: Physical, 368, 115152.

5. Nasiri, H., Baghban, H., Teymouri-Mofrad, R., & Mokhtarzadeh, A. (2023). Chitosan/polyaniline/graphene oxide-ferrocene thin film and highly-sensitive surface plasmon sensor for glucose detection. Optical and Quantum Electronics, 55(11), 948.

Dr. Deepakkumar R | Engineering | Best Researcher Award

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Dr. Deepakkumar R | Engineering | Best Researcher Award

Assistant Professor | Vellore Institute of Technology | India

Dr. Deepakkumar R is a distinguished Engineering academician and researcher with expertise in Computational Fluid Dynamics, Mechanical Engineering, and Thermal Engineering. His Engineering career reflects deep engagement with teaching, research, and innovation in advanced Engineering systems such as heat exchangers, solar air heaters, hydrogen storage, and fuel cells. He has contributed significantly to Engineering research through his studies on vortex shedding, phase change materials, and multiphase flow analysis. His professional experience includes serving at leading Engineering institutions such as VIT Vellore, SRM Institute of Science and Technology, NIT Andhra Pradesh, and IIITDM Kancheepuram, where he guided numerous Engineering projects and doctoral candidates. His Engineering education spans from a Bachelor’s in Mechanical Engineering to a Ph.D. in Mechanical Engineering from IIITDM Kancheepuram, emphasizing Computational Engineering and simulation of fluid flows. Dr. Deepakkumar’s research skills include expertise in CFD tools like ANSYS Fluent, CATIA, Tecplot, and MATLAB, combined with experimental proficiency in wind and water tunnel analysis. His contributions to Engineering education and innovation have been recognized through multiple awards, including the “Outstanding Research Award” and “Best Research Paper Award,” underlining his excellence in Engineering research and pedagogy. His innovative work also extends to design registration in heat exchanger technology, showcasing his Engineering creativity and applied problem-solving capability. Overall, Dr. Deepakkumar R exemplifies the integration of Engineering research, teaching, and technology-driven innovation, continuously contributing to sustainable and renewable energy systems within the broader Engineering community. His Scopus profile of 184 Citations, 22 Documents, 7 h-index.

Profiles: Scopus | Google Scholar | ORCID

Featured Publications

1. Deepakkumar, R., & Jayavel, S. (2017). Air side performance of finned-tube heat exchanger with combination of circular and elliptical tubes. Applied Thermal Engineering, 119, 360–372.

2. Deepakkumar, R., Jayavel, S., & Tiwari, S. (2017). Cross flow past circular cylinder with waviness in confining walls near the cylinder. Journal of Applied Fluid Mechanics, 10(1), 183–197.

3. Ramalingam, S., Babu, D., Deepakkumar, R., & Malinee, S. (2022). Effect of Moringa oleifera biodiesel–diesel–carbon black water emulsion blends in diesel engine characteristics. Energy Reports, 8, 9598–9609.

4. Deepakkumar, R., & Jayavel, S. (2018). Effect of local waviness in confining walls and its amplitude on vortex shedding control of the flow past a circular cylinder. Ocean Engineering, 156, 208–216.

5. Ramalingam, S., Babu, D., Santhoshkumar, A., Deepakkumar, R., & Ravikanth, D. (2022). Impact of exhaust gas recirculation and split injection strategy combustion behavior on premixed charge compression ignition engine fuelled with moringa oleifera methyl ester. Fuel, 319, 123702.