Muhammad Khan – Semiconductor – Best Scholar Award 

Posted on by AMO Physics

Mr. Muhammad Khan's academic journey began with a strong foundation in physics, completing his B.Sc. in Mathematics and Physics at the University of the Punjab, Lahore, Pakistan. He further advanced his studies by obtaining an MSc in Physics from the same institution, followed by an MS in Physics from International Islamic University, Islamabad, Pakistan, where he focused on the optical properties of nitrogen-implanted GaAs. His academic excellence and passion for research led him to pursue a PhD in Condensed Matter Physics at Peking University, Beijing, China, under the supervision of Prof. Xiaodong Hu. His doctoral research revolved around dislocations reduction and phase modulation in MOCVD heteroepitaxial growth of GaN, laying the groundwork for his expertise in semiconductor materials and device applications.

💼 Professional Endeavors

With a distinguished academic background, Mr. Muhammad Khan embarked on a diverse professional journey, holding positions in both academia and research. His career includes roles as a Research Scientist at the National Center for Physics, Quaid-i-Azam University, Islamabad, where he focused on the optical properties of ion-implanted boron nitride thin films. He also served as a Postdoctoral Research Associate and Lecturer in the Department of Physics at the University of Azad Jammu and Kashmir, Pakistan, where he conducted groundbreaking research on hexagonal boron nitride nanostructures and taught advanced quantum mechanics. His earlier professional experiences as a Senior Science Teacher at Fazaia Inter College Nur Khan, Rawalpindi, and Science Teacher at various institutions reflect his commitment to education and scientific dissemination.

🔬 Contributions and Research Focus

Mr. Khan's research is centered on the growth and characterization of III-V semiconductors, particularly gallium nitride (GaN) and its applications in light-emitting diodes (LEDs) and ultraviolet photodetectors (PDs). His expertise spans multiple advanced techniques, including metal-organic chemical vapor deposition (MOCVD) and chemical vapor deposition (CVD) for semiconductor growth. Additionally, he has extensively worked with various characterization tools such as scanning electron microscopy (SEM), atomic force microscopy (AFM), transmission electron microscopy (TEM), Raman spectroscopy, and X-ray diffraction (XRD). His work also involves simulation of III-nitride devices using Crosslight and APSYS simulation tools, contributing to advancements in semiconductor device fabrication.

🌍 Impact and Influence

Mr. Khan’s impact on the semiconductor industry is evident through his active participation in high-impact research projects and collaborations with esteemed scientists. With over 100 citations and an h-index of 6, his research has been recognized internationally. He has contributed significantly to projects funded by prestigious organizations such as the Higher Education Commission (HEC) of Pakistan and the Beijing Municipal Science & Technology Commission, focusing on enhancing GaN growth, reducing dislocation densities, and improving material properties for device applications. His work has practical implications in biomedical and nuclear applications, broadening the scope of semiconductor research.

🏆Academic Cites

Mr. Khan’s research publications in reputable journals have received significant citations, demonstrating the scientific community's recognition of his work. His contributions to gallium nitride growth, ion implantation, and device fabrication serve as valuable references for researchers in the field. His role as a key participant and doctoral researcher in multiple Beijing Municipal Science & Technology Commission projects further underscores the relevance and impact of his work.

🌟 Legacy and Future Contributions

With a career objective to become a world-leading expert in semiconductor growth and device fabrication, Mr. Muhammad Khan’s future contributions are expected to push the boundaries of III-V semiconductor research. His ongoing research on hexagonal boron nitride nanostructures and their applications in biomedical and nuclear fields indicates his forward-thinking approach. By continuing his work in semiconductor materials, his legacy will be defined by innovations that shape the next generation of electronic and optoelectronic devices.

📝Semiconductor

Mr. Muhammad Khan’s expertise in semiconductor research has led to significant advancements in gallium nitride growth and device applications. His work on semiconductor characterization techniques has contributed to improving material properties for LEDs and photodetectors. Future developments in semiconductor technology will be greatly influenced by his pioneering research in III-V compounds and heteroepitaxial growth.

Notable Publication

📝Wafer-Scale Heteroepitaxy GaN Film Free of High-Density Dislocation Region with Hexagonal 3D Serpentine Mask

Authors: Lei, M.; Chen, H.; Khan, M.S.A.; Zong, H.; Hu, X.

Journal: Applied Surface Science Advances

Year: 2023

Access: Open Access

Kiran Aftab – Analytical Chemistry – Best Researcher Award 

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Dr. Kiran Aftab's academic journey began with a strong foundation in chemistry, demonstrated by her consistent first-division achievements from matriculation through higher education. She obtained her PhD in Chemistry from Government College University Faisalabad/NIBGE in 2013, focusing on the development of cost-effective methodologies for removing toxic metals using fungal biomass. Her earlier research during her M. Phil. in Chemistry (2004) and M.Sc. in Chemistry (2002) at the University of Agriculture, Faisalabad, revolved around pigment production and the chemical treatment of natural resources. Her early academic pursuits set the stage for her future contributions to analytical chemistry and environmental safety.

💼 Professional Endeavors

Dr. Aftab has been actively involved in academia, research, and administrative roles at Government College University Faisalabad (GCUF) and GC Women University Faisalabad (GCWUF). She has participated in numerous professional training programs, including workshops on nanomaterials characterization techniques, business incubation, food safety, innovation in biotechnology, and scientific research methodologies. Her leadership roles include serving as Secretary of the Board of Studies, Departmental Focal Person for Business Incubation, and Deputy Director of the Student Start-Up Business Center at GCWUF. These responsibilities reflect her commitment to fostering academic excellence and research-driven entrepreneurship.

🔬 Contributions and Research Focus

Dr. Aftab’s primary research focuses on analytical chemistry, with significant contributions to environmental chemistry, toxic metal removal, and pigment optimization. Her PhD research introduced innovative approaches for removing toxic metals like lead (Pb) and zinc (Zn) using fungal biomass, demonstrating her dedication to sustainable and cost-effective environmental solutions. She has published extensively in high-impact journals and contributed as a reviewer for prestigious international journals, including Journal of Hazardous Materials, Water Research, Ecotoxicology and Environmental Safety, and Journal of Food Science and Technology. Her expertise extends to chemical analysis, bioremediation, and industrial applications of chemical methodologies.

🌍 Impact and Influence

Dr. Aftab’s influence in analytical chemistry is reflected in her role as an external examiner for M.Sc., M.Phil., and PhD evaluations at leading universities such as Punjab University, University of Sargodha, and Bahauddin Zakariya University. Her administrative roles in business incubation and research innovation highlight her impact beyond academic teaching. As a member of various editorial boards and scientific committees, she actively shapes the discourse in modern chemistry research. Her involvement in technology entrepreneurship workshops and innovation summits demonstrates her commitment to bridging the gap between academia and industry.

🏆Academic Cites

Dr. Aftab's research has gained significant recognition in the scientific community, with her publications cited in numerous studies related to analytical chemistry, toxic metal removal, and environmental safety. Her contributions to peer-reviewed journals and editorial roles further validate the importance of her work in shaping modern chemical research. Her research findings are frequently referenced in studies exploring innovative chemical processes for environmental sustainability.

🌟 Legacy and Future Contributions

Dr. Kiran Aftab’s legacy is deeply rooted in her contributions to analytical chemistry, particularly in developing eco-friendly and efficient methodologies for chemical analysis and environmental remediation. Her future contributions aim to enhance the application of analytical chemistry in industrial and environmental settings, ensuring the sustainability and efficiency of chemical processes. As a mentor, researcher, and administrator, she continues to inspire the next generation of chemists through her innovative research and leadership.

📝Analytical Chemistry

Dr. Kiran Aftab has made significant contributions to analytical chemistry, particularly in the fields of toxic metal removal and pigment optimization. Her extensive research in analytical chemistry has advanced environmental sustainability and chemical process efficiency. The impact of analytical chemistry on industrial applications continues to grow under her leadership and research expertise.

Notable Publication

📝Optimizing Acidogenic Fermentation for NiFe₂O₄-rGO Nanoparticles Enhanced Biohydrogen Generation Using Box-Behnken Design

Authors: Jannat, F.T., Aftab, K., Akhtar, K., Khan, S.G., Ali, M.

Journal: Fuel

Year: 2025

Citations: 0

📝Advancing Lignocellulosic Biomass Pretreatment with Nanotechnology: A Comprehensive Bibliometric Analysis

Authors: Shakeel, H., Aftab, K., Jannat, F.T., Umbreen, H., Noreen, R.

Journal: Cellulose

Year: 2025

Citations: 0

📝Electrocatalytic Performance of Modified NiFe₂O₄/rGO Composite Deposited on Fluorine-Doped Tin Oxide Electrode Using Polyvinylidene Fluoride Binder

Authors: Javed, N., Aftab, K., Jannat, F.T., Siddique, Z.

Journal: Journal of Materials Research

Year: 2025

Citations: 0

Evgeniy Prokhorov – Chemical Physics – Best Researcher Award 

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Prof. Evgeniy Prokhorov demonstrated an early passion for scientific exploration, particularly in the field of physicochemical hydrodynamics. His academic journey led him to pursue advanced studies in combustion and explosion physics, culminating in the defense of his doctoral thesis in 2005. His research on unsteady detonation processes in gases and rarefied gas mixtures laid the foundation for his significant contributions to the field of chemical physics. His rigorous academic training equipped him with the necessary expertise to explore complex physical and chemical interactions in fluid dynamics.

💼 Professional Endeavors

Currently serving as a leading researcher at the Institute of Hydrodynamics SB RAS, Prof. Prokhorov has dedicated his career to advancing the understanding of combustion, explosion physics, and fluid dynamics. His professional endeavors include extensive research into chemical physics, particularly in the study of detonation processes and rarefied gas mixtures. His work has been instrumental in the development of models that explain the behavior of reacting flows, making critical contributions to both theoretical and applied sciences.

🔬 Contributions and Research Focus

Prof. Prokhorov’s research primarily focuses on chemical physics, with a strong emphasis on physicochemical hydrodynamics and detonation phenomena. His work has provided valuable insights into the mechanisms of unsteady detonation waves, contributing to both fundamental research and practical applications in energy, defense, and propulsion systems. His extensive publication record, with over 100 scientific papers, reflects his dedication to pushing the boundaries of knowledge in his field. His studies have significantly influenced the understanding of reaction kinetics and combustion stability in gas mixtures.

🌍 Impact and Influence

The impact of Prof. Prokhorov’s work extends beyond academia, influencing industrial applications and technological advancements in detonation-based propulsion and energy systems. His contributions to chemical physics have shaped modern approaches to modeling combustion dynamics and explosion control. As a respected figure in the scientific community, he has collaborated with leading researchers, contributing to the broader understanding of high-energy reactions and their applications.

🏆Academic Cites

With over 100 published scientific papers, Prof. Prokhorov’s research has been widely cited in the fields of physicochemical hydrodynamics, combustion science, and detonation physics. His work has served as a foundation for numerous studies on unsteady detonation, rarefied gas dynamics, and explosion modeling, making a lasting impact on the field of chemical physics. His high citation count reflects the relevance and significance of his contributions to both theoretical research and applied sciences.

🌟 Legacy and Future Contributions

Looking forward, Prof. Evgeniy Prokhorov aims to further advance the study of combustion and detonation processes, developing more accurate predictive models for high-energy reactions. His continued research in chemical physics is expected to enhance scientific understanding and practical applications in areas such as aerospace propulsion, safety engineering, and energy production. His legacy as a leading researcher at the Institute of Hydrodynamics SB RAS ensures that his work will inspire future generations of scientists in the field of physicochemical hydrodynamics.

📝Notable Publication

📝Modeling of Detonation Combustion of Carbon Dust

Author: Prokhorov, E.S. (Evgeniy S.)

Journal: Combustion, Explosion and Shock Waves

Year: 2024

Citations: 0

📝Simulation of Gaseous Detonation of Hydrocarbon Fuel under Oxygen Lack

Author: Prokhorov, E.S. (Evgeniy S.)

Journal: Combustion, Explosion and Shock Waves

Year: 2023

Citations: 0

📝Unified Approach to Modeling Equilibrium Flows of Detonating Gases

Author: Prokhorov, E.S. (Evgeniy S.)

Journal: Journal of Engineering Physics and Thermophysics

Year: 2023

Citations: 1

Sanjay Krishna – Semiconductor Infrared Detectors – Best Researcher Award 

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Prof. Sanjay Krishna’s academic journey began with a strong foundation in physics, earning a B.Sc (Hons) from S.S.I.H.L Bangalore in 1994. His passion for scientific discovery led him to obtain an M.Sc in Physics from the Indian Institute of Technology, Madras in 1996. Expanding his expertise, he pursued graduate studies in Electrical Engineering and Applied Physics at the University of Michigan, Ann Arbor, earning an M.S. in 1999 and a Ph.D. in 2001. These formative years provided him with a deep understanding of physics, semiconductor technology, and optoelectronics, setting the stage for his groundbreaking work in Semiconductor Infrared Detectors.

💼 Professional Endeavors

Prof. Krishna has established himself as a leader in the field of Semiconductor Infrared Detectors, holding prestigious academic and industry positions. Since 2017, he has served as the George R. Smith Chair Professor at Ohio State University’s Electrical and Computer Engineering Department. His role as Graduate Chair of the ECE Department (2023-Present) further highlights his influence in shaping the next generation of engineers. Additionally, he has played a crucial role in technology commercialization, co-founding SK Infrared and serving as CTO to develop infrared detector applications for defense and commercial markets. His extensive collaborations with universities, industry leaders, and the U.S. Department of Defense have positioned him as a key figure in infrared technology innovation.

🔬 Contributions and Research Focus

A central focus of Prof. Krishna’s research has been Semiconductor Infrared Detectors, particularly in advancing Type-II Superlattice (T2SL) detectors. His pioneering work includes the development of SLS nBn detectors (Rodriquez et al, APL, 2007) and dual-band SLS nBn detectors (Khoshakhlagh et al, APL, 2007). His expertise spans low-noise avalanche photodetectors, LIDAR technologies, and bandstructure-engineered photodiodes for space applications. His groundbreaking contributions have led to major funded projects, including the Low Excess-Noise Avalanche Photodetectors (LEAPS) project ($3M) and the NASA BETA-APD for space LIDAR ($1.2M). His research has revolutionized the efficiency and performance of Semiconductor Infrared Detectors, making them more reliable and applicable across various fields.

🌍 Impact and Influence

Prof. Krishna’s impact extends far beyond academia. He has received over $14M in research funding since joining Ohio State in 2017, reflecting the significance of his contributions. His leadership in setting up Ohio State’s Nanotech West user facility and his role as Director of the University of New Mexico’s Center for High Tech Materials (2013-2016) have been instrumental in advancing semiconductor research. His collaborations with NASA, the Office of Naval Research, and major defense contractors have positioned him at the forefront of infrared sensing technology. His innovations have influenced industry standards, shaping the future of Semiconductor Infrared Detectors for military, space, and commercial applications.

🏆Academic Cites

With over 400 publications, more than 16,000 citations, and an H-index of 62, Prof. Krishna’s research is widely recognized in the scientific community. His highly cited papers in journals like Nature Photonics and Applied Physics Letters underscore the lasting impact of his work. Notably, his paper on Terahertz Compressive Imaging (Watts et al., Nature Photonics, 2014) has over 920 citations, demonstrating its influence on imaging technology. His extensive contributions to Semiconductor Infrared Detectors are foundational for future advancements in this rapidly evolving field.

🌟 Legacy and Future Contributions

Prof. Krishna’s legacy is deeply rooted in innovation, mentorship, and commercialization. As a Fellow of SPIE, IEEE, and the Optical Society of America, his leadership is widely acknowledged. His accolades, including the IEEE Photonics Society Aron Kressel Award (2020) and SPIE Technology Achievement Award (2020), highlight his contributions to optoelectronics and sensor technology. Looking ahead, he aims to further integrate machine learning with infrared imaging, enhance detector performance, and develop next-generation quantum dot photodetectors. His efforts in entrepreneurship and academia will continue to drive advancements in Semiconductor Infrared Detectors, ensuring his contributions remain a cornerstone of infrared sensing technology.

📝Semiconductor Infrared Detectors

Prof. Krishna’s groundbreaking research in semiconductor infrared detectors has led to key advancements in quantum dot infrared photodetectors and superlattice-based sensing technologies. His future work will continue to revolutionize the field of semiconductor infrared detectors, paving the way for next-generation sensing and imaging solutions.

Notable Publication

📝Enhanced UV–Vis Rejection Ratio in Metal/BaTiO3/β-Ga2O3 Solar-Blind Photodetectors

Authors: Wriedt, N., Meng, L., Yu, D., McGlone, J.F., Rajan, S.

Journal: Advanced Electronic Materials

Year: 2025

Citations: 1

📝Low Excess Noise and High Quantum Efficiency Avalanche Photodiodes for Beyond 2 µm Wavelength Detection

Authors: Jung, H., Lee, S., Jin, X., David, J.P., Krishna, S.S.R.

Journal: Communications Materials

Year: 2024

Citations: 1

📝Electroabsorption in InGaAs and GaAsSb p-i-n Photodiodes

Authors: Liu, Y., Jin, X., Jung, H., Krishna, S.S.R., David, J.P.

Journal: Applied Physics Letters

Year: 2024

Citations: 0

📝Active Interface Characteristics of Heterogeneously Integrated GaAsSb/Si Photodiodes

Authors: Muduli, M., Xia, Y., Lee, S., Arafin, S., Krishna, S.S.R.

Journal: Applied Physics Letters

Year: 2024

Citations: 0

📝Structural and Electrical Properties of Grafted Si/GaAsSb Heterojunction

Authors: Abbasi, H.N., Lee, S., Jung, H., Ma, Z., Krishna, S.S.R.

Journal: Applied Physics Letters

Year: 2024

Citations: 4

📝Infrared Barrier Detectors with Metamorphic InAsSb Absorbers on GaAs Substrates

Authors: Gawron, W., Madejczyk, P., Martyniuk, P.M., Krishna, S.S.R.

Journal: IEEE Sensors Journal

Year: 2024

Citations: 1

📝Digital Alloy-Grown InAs/GaAs Short-Period Superlattices with Tunable Band Gaps for Short-Wavelength Infrared Photodetection

Authors: Guo, B., Liang, B., Zheng, J., Ghosh, A.W., Campbell, J.C.

Journal: ACS Photonics

Year: 2024

Citations: 3

Serhii Pokutnii – Quantum Optics Nanosystems – Optical Physics Excellence Award

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Prof. Dr. Serhii Pokutnii began his academic journey at Dnipropetrovsk State University, where he pursued a degree in physics from 1973 to 1978. His strong passion for theoretical physics led him to postgraduate studies at the Institute of Spectroscopy of the Russian Academy of Sciences (Moscow) from 1980 to 1984. During this period, he engaged in advanced research in quantum optics nanosystems, laying the foundation for his future contributions to the field. His dedication to scientific inquiry culminated in earning a PhD in 1988, marking the beginning of a distinguished academic career.

💼 Professional Endeavors

Prof. Pokutnii has held several prestigious academic positions throughout his career, making significant contributions to theoretical quantum optics and nanophotonics. He served as the Head of the Department of Theoretical Physics at Krivoy Rog State University of Ukraine from 1988 to 2008. His academic influence extended beyond Ukraine, with appointments as a Professor at the Institute of Spectroscopy, Russian Academy of Sciences (1996) and Wrocław University of Technology, Poland (1998-2002). From 2008 to 2010, he played a key role in scientific research development as Vice-Rector at Zhytomyr State University. His leadership continued as Head of Theoretical Problems of Optics and Spectroscopy Nanosystems at Kurdjumov Institute for Metal Physics (2006-2013) and later as Group Leader for Theoretical Quantum Optics of Nanosystems at the Institute of Physics of the National Academy of Sciences of Ukraine (2019-present).

🔬 Contributions and Research Focus

Prof. Pokutnii’s research has been instrumental in advancing quantum optics nanosystems, particularly in the areas of exciton and biexciton states in semiconductor nanostructures, photonic quasicrystals, and magneto-electrooptics nanosystems. His work focuses on developing nanoheterostructures using semiconductor and dielectric quantum dots (QDs) to create optical nanolasers and strongly light-absorbing structures. Additionally, he has contributed to the theoretical quantum optics and spectroscopy of perovskite nanocrystals, which have significant applications in modern photonics. His theoretical models in condensed matter physics have provided deep insights into the behavior of excitons, local electron states, and energy transfer mechanisms in nanosystems.

🌍 Impact and Influence

Prof. Dr. Pokutnii's contributions have had a profound impact on nanophotonics, quantum optics, and condensed matter physics. His work on quantum optics nanosystems has been widely recognized by the international scientific community. He has received several prestigious honors, including the Soros Grant for Research (1993), Soros Professor Award (1998), and the Polish Academy of Sciences Grant (2000). His leadership in editorial roles further highlights his influence in the field. He has served as Senior Editor of the Journal of Nanosciences Letters (2012-2015), Associate Editor of the Journal of Nanophotonics (2015-2018), and Topic Editor for multiple scientific journals. His extensive editorial work has helped shape contemporary research trends in quantum optics and nanophotonics.

🏆Academic Cites

Prof. Pokutnii’s research has been widely cited in leading academic journals, demonstrating the significant impact of his contributions to quantum optics nanosystems. His books, such as Advances in Semiconductor Research. Physics of Nanosystems, Spintronics and Technological Applications (2015) and Optics and Spectroscopy of Exciton States in Quasi-Zero-Dimensional Nanosystems (2016), are considered foundational texts in the field. His editorial works and published research articles continue to serve as essential references for researchers worldwide.

🌟 Legacy and Future Contributions

Prof. Dr. Serhii Pokutnii’s legacy is defined by his pioneering research in theoretical quantum optics and spectroscopy nanosystems. His future contributions are expected to further advance the understanding of nanophotonic quantum systems, enabling breakthroughs in optical nanolasers, perovskite nanocrystals, and terahertz-emitting nanosystems. His continued leadership at the Institute of Physics, National Academy of Sciences of Ukraine, ensures that his impact on the next generation of physicists and researchers remains profound. By bridging theoretical physics with cutting-edge nanotechnology applications, Prof. Pokutnii is solidifying his place as a leading figure in quantum optics nanosystems.

📝Quantum Optics Nanosystems

Prof. Dr. Serhii Pokutnii’s groundbreaking research in quantum optics nanosystems has revolutionized the field of theoretical physics and nanophotonics. His pioneering work in quantum optics nanosystems has provided crucial insights into exciton dynamics and photonic quasicrystals. As a leading scientist in quantum optics nanosystems, his future contributions are expected to further enhance advanced optical technologies and semiconductor nanostructures.

Notable Publication

Title: The Splitting of Electron States in Ge/Si Nanosystem with Germanium Quantum Dots

Journal: Physica B: Condensed Matter

Year: 2021

Title: The Splitting of Electron States in Ge/Si Heterostructure with Germanium Quantum Dots

Journal: physica status solidi (b)

Year: 2020

Title: Optical Absorption by a Nanosystem with Dielectric Quantum Dots

Journal: The European Physical Journal Plus

Year: 2020

Title: Polarizability of Germanium Quantum Dots with Spatially Separated Electrons and Holes

Journal: The European Physical Journal Plus

Year: 2020

Sitender Kashyap – String Theory – Best Researcher Award 

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Dr. Sitender Kashyap’s academic journey began with a strong foundation in physics. He pursued his M.Sc. in Physics at the Centre for Excellence in Basic Sciences, Mumbai, from 2007 to 2012, where he distinguished himself as one of the top 1% in the National Graduate Physics Exam conducted by the Indian Association of Physics Teachers. His early academic success earned him the prestigious INSPIRE Scholarship awarded by the Ministry of Science and Technology, India. His passion for theoretical physics led him to pursue a Ph.D. at the Harish-Chandra Research Institute, Allahabad, from 2012 to 2018, where he worked on String Theory, focusing on massive states in pure spinor superstrings and vacuum decay implications.

💼 Professional Endeavors

Dr. Sitender Kashyap has made significant contributions to theoretical physics, particularly in String Theory. He has been actively engaged in research, academic discussions, and international collaborations. His expertise was recognized with the Physics for Future (PF4) Postdoctoral Fellowship under the Marie Sklodowska-Curie Actions COFUND in 2024. He has been an active participant in prestigious conferences, including the Strings 2018 Fellowship at the Okinawa Institute of Science and Technology and various National and Indian Strings Meetings across India. His professional engagements also include invited talks at institutions such as the Chennai Mathematical Institute and IIT Indore.

🔬 Contributions and Research Focus

Dr. Kashyap’s research focus lies in String Theory, particularly in the study of massive states in pure spinor superstring theory and vacuum decay. His work provides critical insights into the fundamental aspects of quantum gravity and high-energy physics. His participation in the Perimeter Institute for Theoretical Physics (2016) and collaborations with leading theoretical physicists such as Dr. Roji Pius have further strengthened his contributions to the field. His research has been instrumental in advancing our understanding of String Theory, bridging gaps between mathematical formalism and physical interpretations.

🌍 Impact and Influence

Dr. Sitender Kashyap’s impact in String Theory is reflected in his invited talks and academic collaborations across prestigious institutions. His role as a speaker at events such as Numerical and Analytical Relativity-2024 (IIIT Allahabad) and Chennai Strings Meetings (2022, 2023) showcases his expertise and influence in the field. His recognition with the Bharat Vikas Award in 2022 by the Institute of Self Reliance, Bhubaneshwar, further highlights his contributions to theoretical physics.

🏆Academic Cites

Dr. Kashyap’s research has been widely cited in academic literature, underscoring the significance of his work in String Theory. His publications in internationally recognized journals have been referenced by leading physicists, demonstrating the impact of his theoretical models and findings. His ability to engage with cutting-edge topics in superstring theory, vacuum decay, and high-energy physics has positioned him as a prominent researcher in the field.

🌟 Legacy and Future Contributions

Dr. Sitender Kashyap’s legacy in String Theory continues to grow as he advances his postdoctoral research. His future contributions are expected to delve deeper into the intricacies of quantum gravity and theoretical models, influencing both academia and scientific advancements. His participation in high-profile conferences, mentorship of young physicists, and ongoing research ensure that his impact on the field will be long-lasting. With continued international collaborations and recognition, Dr. Kashyap is poised to play a pivotal role in shaping the future of String Theory.

📝Notable Publication

📝Closed Superstring Field Theory and Its Applications

Authors: C. de Lacroix, H. Erbin, S. P. Kashyap, A. Sen, M. Verma

Journal: International Journal of Modern Physics A

Year: 2017

Citations: 133

📝Subleading Soft Theorem for Multiple Soft Gravitons

Authors: S. Chakrabarti, S. P. Kashyap, B. Sahoo, A. Sen, M. Verma

Journal: Journal of High Energy Physics

Year: 2017

Citations: 65

📝Testing Subleading Multiple Soft Graviton Theorem for CHY Prescription

Authors: S. Chakrabarti, S. P. Kashyap, B. Sahoo, A. Sen, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 31

📝Amplitudes Involving Massive States Using Pure Spinor Formalism

Authors: S. Chakrabarti, S. P. Kashyap, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 13

📝Theta Expansion of First Massive Vertex Operator in Pure Spinor

Authors: S. Chakrabarti, S. P. Kashyap, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 12

📝Integrated Massive Vertex Operator in Pure Spinor Formalism

Authors: S. Chakrabarti, S. P. Kashyap, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 11

Lewis Antill – Quantum Biology – Best Researcher Award

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Prof. Lewis Antill’s academic journey began with an exceptional performance in chemistry, leading him to pursue an MChem in Chemistry at the University of Leicester, UK, where he graduated with First-Class Honors. His passion for research took him to the University of Stuttgart, Germany, for a year abroad, where he contributed to innovative projects on liquid crystalline aryl guanidinium ions and atmospheric hydroxyl radical reactivity. Building upon this strong foundation, he pursued a PhD in Environmental Sciences at The University of Tokyo, where he specialized in spatially resolved microspectroscopy of flavin-based magnetosensitive photochemistry under the supervision of Prof. Jonathan R. Woodward. Graduating as valedictorian, he was also awarded The First National High School Memorial Award for his outstanding academic performance.

💼 Professional Endeavors

Prof. Antill’s career has spanned some of the most prestigious research institutions worldwide. His research career includes roles as a Research Associate in Laser Photochemistry and Spectroscopy at the University of Oxford, where he contributed to the Spin Chemistry collaboration under the ERC Synergy Grant QuantumBirds. His work there focused on developing sensitive optical spectroscopic techniques to investigate the kinetics of photochemical processes and their interaction with magnetic fields. Before his Oxford tenure, he was a Special Project Researcher at Saitama University/Japan Science and Technology Agency (JST) PRESTO, where he led independent research on spatiotemporal measurement of cryptochromes for animal magnetoreception, securing 480 million KRW in grant funding. His current position as a Research Professor at Sungkyunkwan University and Visiting Academic at the University of Oxford highlights his ongoing influence in quantum biology.

🔬 Contributions and Research Focus

Prof. Antill’s research has been at the forefront of quantum biology, particularly in understanding the role of flavins, flavoproteins, and cryptochromes in biological magnetoreception. His expertise spans high-sensitivity fluorescence and transient-absorption-based microspectroscopies, which he designed and developed to probe fundamental biological photochemical reactions. His work has significant implications for understanding how biological systems interact with magnetic fields at the quantum level, a topic that has intrigued the scientific community for decades. His pioneering research on quantum biology has contributed to a deeper understanding of the molecular basis of magnetoreception in animals, potentially paving the way for breakthroughs in bio-inspired quantum technologies.

🌍 Impact and Influence

Prof. Antill’s impact on the scientific community is evident through his numerous awards, including the Best Presentation Award at the Quantum Life Science Society Conference (2021), the Best Poster Prize at the Spin Chemistry Meeting (2017), and his recognition as valedictorian of his PhD cohort at The University of Tokyo. His work has been recognized not only through citations in top-tier journals but also through substantial funding and scholarships, such as the MEXT Scholarship for PhD, the EFEPR Scholarship from the International EPR Society, and the ERASMUS Scholarship for MChem. His involvement in multiple international collaborations and his role in developing cutting-edge spectroscopic methodologies further reinforce his standing as a thought leader in quantum biology.

🏆Academic Cites

Prof. Antill’s research has been extensively cited in leading journals, demonstrating the broad influence of his work in quantum biology and spin chemistry. His findings on magnetosensitive photochemistry and cryptochrome-based biological magnetoreception have been referenced by researchers across diverse fields, from biophysics to environmental sciences. His ability to bridge fundamental chemistry, physics, and biology has made his work invaluable to the scientific community.

🌟 Legacy and Future Contributions

Prof. Antill’s legacy lies in his contributions to quantum biology, where his pioneering research on cryptochromes and flavoproteins has reshaped our understanding of biological magnetoreception. His future contributions are expected to further expand the applications of quantum effects in biological systems, potentially leading to advancements in bio-inspired quantum computing, environmental sensing, and biomedical imaging. His ongoing research at Sungkyunkwan University and the University of Oxford ensures that he will continue to push the boundaries of interdisciplinary science, inspiring the next generation of researchers to explore the quantum mechanisms underlying life itself.

📝Notable Publication

📝Optical absorption and magnetic field effect based imaging of transient radicals

Authors: J. P. Beardmore, L. M. Antill, J. R. Woodward

Journal: Angewandte Chemie International Edition

Year: 2015

Citations: 36

📝Ionic liquid crystals derived from guanidinium salts: induction of columnar mesophases by bending of the cationic core

Authors: L. M. Antill, M. M. Neidhardt, J. Kirres, S. Beardsworth, M. Mansueto, A. Baro, ...

Journal: Liquid Crystals

Year: 2014

Citations: 26

📝Flavin adenine dinucleotide photochemistry is magnetic field sensitive at physiological pH

Authors: L. M. Antill, J. R. Woodward

Journal: The Journal of Physical Chemistry Letters

Year: 2018

Citations: 25

📝Time-resolved optical absorption microspectroscopy of magnetic field sensitive flavin photochemistry

Authors: L. M. Antill, J. P. Beardmore, J. R. Woodward

Journal: Review of Scientific Instruments

Year: 2018

Citations: 13

📝Dimerization of European robin cryptochrome 4a

Authors: M. Hanić, L. M. Antill, A. S. Gehrckens, J. Schmidt, K. Görtemaker, ...

Journal: The Journal of Physical Chemistry B

Year: 2023

Citations: 9

📝Photoinduced flavin-tryptophan electron transfer across vesicle membranes generates magnetic field sensitive radical pairs

Authors: L. M. Antill, S. Takizawa, S. Murata, J. R. Woodward

Journal: Molecular Physics

Year: 2019

Citations: 6

📝RadicalPy: A Tool for Spin Dynamics Simulation

Authors: L. M. Antill, E. Vatai

Journal: Journal of Chemical Theory and Computation

Year: 2024

Citations: 2

Yuxiang Weng – Energy Transfer in Photosynthesis – Best Researcher Award 

Posted on by AMO Physics

Professor Yuxiang Weng began his academic journey with a strong foundation in chemistry and physics. He obtained his Bachelor of Science in Chemistry from East China Normal University in Shanghai, China, in 1985. His academic excellence led him to pursue a Master’s degree in Physical Chemistry, specializing in chemical thermodynamics and kinetics, at the same institution from 1985 to 1988. His master's thesis focused on pattern generation in the Belousov-Zhabotinskii reaction, a fundamental study of nonlinear chemical dynamics. Driven by a passion for laser physics, he furthered his studies at the Institute of Physics, Chinese Academy of Sciences, earning his PhD in Science in 1993. His doctoral research concentrated on the UV laser photolysis of 1,2-dichloroethane, marking the beginning of his expertise in laser physics and photochemistry.

💼 Professional Endeavors

Prof. Weng’s professional journey has been a blend of academia and research, shaping him into a leader in laser physics and photochemistry. He started his career as a Teaching Assistant at Nanjing Medical College from 1988 to 1990, where he laid the groundwork for his teaching and mentoring skills. After completing his PhD, he joined the State Key Laboratory of Structural Chemistry at the Institute of Chemistry, Chinese Academy of Sciences, as a Research Fellow (1993-1994), where he worked on chemical structures and reactions at the molecular level.

His international research experience expanded through postdoctoral fellowships at The University of Hong Kong (1994-1997) and Emory University, USA (1997-2000), where he delved deeper into laser-matter interactions and molecular photophysics. In 1999, he returned to China as a Professor in Laser Physics and Chemistry at the Institute of Physics, Beijing, where he continues to contribute to the advancement of scientific knowledge.

🔬 Contributions and Research Focus

Prof. Weng has dedicated his research to light-matter interactions, ultrafast spectroscopy, and energy transfer in photosynthesis. His pioneering work in femtosecond-time resolved fluorescence spectrometry has enhanced the understanding of energy transfer mechanisms in complex biological systems. His research on dynamical structures and chemical modifications of large biological molecules has provided valuable insights into molecular behavior under various conditions. Additionally, his contributions to the spatial and temporal characterization of photogenerated carriers have led to significant advancements in laser spectroscopy.

🌍 Impact and Influence

Prof. Weng’s work has had a profound impact on both fundamental research and applied sciences. His research has not only advanced knowledge in energy transfer in photosynthesis but also influenced various interdisciplinary fields, including renewable energy, environmental science, and biomedical imaging. His leadership in NSFC-funded projects has fostered collaborations between physicists, chemists, and biologists, enhancing the scientific understanding of photophysical processes.

As a recognized scientist, he has mentored numerous students and postdoctoral researchers, many of whom have gone on to make significant contributions in academia and industry. His influence extends beyond China, as he actively collaborates with international researchers, strengthening global scientific exchange in photochemistry and laser physics.

🏆Academic Cites

Prof. Weng’s extensive research output has been widely cited in scientific literature, reflecting his influence in laser physics, spectroscopy, and photobiology. His publications on femtosecond fluorescence spectroscopy, photogenerated carrier dynamics, and energy transfer in photosynthesis are frequently referenced by researchers developing new materials for energy conversion and molecular imaging technologies. His high citation count is a testament to the lasting impact of his work in the scientific community.

🌟 Legacy and Future Contributions

Looking ahead, Prof. Weng aims to continue his pioneering work in energy transfer in photosynthesis and laser-based spectroscopy. His future contributions are expected to further advance our understanding of ultrafast photophysical processes, leading to more efficient solar energy conversion technologies and innovative applications in biophotonics. His ongoing mentorship of young scientists and continued research efforts will ensure that his legacy in laser physics and spectroscopy endures for generations to come.

📝Energy Transfer in Photosynthesis

Prof. Yuxiang Weng’s groundbreaking research in energy transfer in photosynthesis has significantly advanced the understanding of light-matter interactions in biological and artificial systems. His expertise in spectroscopy and ultrafast laser dynamics has provided new insights into energy transfer in photosynthesis, influencing future developments in solar energy conversion and molecular imaging. Through his continued research, energy transfer in photosynthesis remains at the forefront of his scientific contributions.

Notable Publication

📝Unveiling charge utilization mechanisms in ferroelectric for water splitting

Authors: J. Zhang, Y. Liu, T. Dittrich, F. Fan, C. Li

Journal: Nature Communications

Year: 2025

Citations: 0

📝Sulfur-vacancy induced asymmetric active site for Bi19S27Br3 nanorods photocatalyzes CO2 conversion to ethylene

Authors: J. Zhao, H. Chen, B. Wang, H. Li, J. Xia

Journal: Applied Catalysis B: Environmental

Year: 2025

Citations: 3

📝IR Fingerprint of the Intermolecular Hydrogen Bond on Amino Acids and Its Relevance to Chaperone Activity of αB-Crystallin

Authors: G. Liao, M. Ruan, Y. Wang, H. Chen, Y. Weng

Journal: Journal of Physical Chemistry B

Year: 2025

Citations: 0

📝OsFKBP12 transduces the sucrose signal from OsNIN8 to the OsTOR pathway in a loosely binding manner for cell division

Authors: Z. Wang, H. Li, Y. Weng

Journal: iScience

Year: 2025

Citations: 0

📝Investigation of Transient Temperature Rising of Light-Harvesting Complex II by Nonradiative Heat Dissipation at the Protein Level

Authors: M. Ruan, Y. Xu, G. Liao, H. Chen, Y. Weng

Journal: Journal of Physical Chemistry Letters

Year: 2025

Citations: 0

📝Quantum phase synchronization via exciton-vibrational energy dissipation sustains long-lived coherence in photosynthetic antennas

Authors: R. Zhu, W. Li, Z. Zhen, S. Qin, Y. Weng

Journal: Nature Communications

Year: 2024

Citations: 10

Sitender Kashyap – String Theory – Best Researcher Award 

Posted on by AMO Physics

Dr. Sitender Kashyap's academic journey began with a strong foundation in physics. He pursued his M.Sc. in Physics at the Centre for Excellence in Basic Sciences, Mumbai, from 2007 to 2012, where he excelled in theoretical and mathematical physics. His academic brilliance was recognized early when he secured a place among the top 1% in the National Graduate Physics Exam conducted by the Indian Association of Physics Teachers in 2010. His passion for theoretical physics led him to pursue a Ph.D. at the Harish-Chandra Research Institute, Allahabad (2012–2018), where he focused on massive states in pure spinor superstring theory and implications of vacuum decay in string theory. This early focus on string theory set the course for his future contributions to theoretical physics.

💼 Professional Endeavors

Dr. Kashyap’s professional career has been defined by prestigious postdoctoral fellowships at top institutions. He started as a Postdoctoral Fellow at the Institute of Physics, Bhubaneshwar (2018–2020), followed by positions at The Institute of Mathematical Sciences, Chennai (2021–2023) and the Chennai Mathematical Institute (2023–2024). His expertise earned him a highly competitive Physics for Future Postdoctoral Fellowship under the Marie Sklodowska-Curie Actions COFUND in 2024 at the Institute of Physics of the Czech Academy of Sciences, Prague. His journey reflects a deep commitment to advancing knowledge in string theory and its broader implications in fundamental physics.

🔬 Contributions and Research Focus

Dr. Kashyap’s research primarily focuses on string theory, with particular emphasis on massive states in the pure spinor formalism and vacuum stability within string theoretical models. His Ph.D. thesis addressed fundamental issues in string theory, offering insights into vacuum decay mechanisms and the role of massive states in superstring theory. Over the years, he has presented his findings at numerous high-profile international conferences, including Strings 2018 (Okinawa Institute of Science and Technology, Japan), Indian Strings Meeting, and National Strings Meetings. His work has significantly contributed to advancing the mathematical structure of string theory and its implications for high-energy physics.

🌍 Impact and Influence

Dr. Kashyap’s influence in the theoretical physics community is evident from his invited talks at leading institutions, including the Perimeter Institute for Theoretical Physics (2016) and the Indian Institute of Technology (2024). He has actively contributed to scientific discourse through lectures at events such as Student Talks on Trending Topics in Theory (ST4) at IIT Indore (2022). His impact extends beyond academia, as he has been recognized with several prestigious awards, including the Bharat Vikas Award (2022) and the Strings 2018 Fellowship (Okinawa Institute of Science and Technology). His engagement in string theory research has made him a key figure in the global theoretical physics community.

🏆Academic Cites

Dr. Kashyap’s research has been widely cited in the field of theoretical and mathematical physics, particularly in areas related to string theory and vacuum decay. His publications and conference presentations have contributed to ongoing discussions on superstring formalism, fundamental symmetries, and high-dimensional field theories. His involvement in major international workshops and collaborations underscores the growing influence of his research in shaping modern developments in theoretical physics.

🌟 Legacy and Future Contributions

Dr. Sitender Kashyap’s legacy in string theory is marked by his innovative contributions to understanding vacuum structures and massive states in superstring theory. Moving forward, he aims to deepen his research in non-perturbative aspects of string theory, bridging the gap between high-energy theoretical models and experimental physics. His role at the Institute of Physics of the Czech Academy of Sciences places him at the forefront of theoretical advancements, where he continues to mentor young researchers and contribute to groundbreaking developments. His future work is expected to further refine our understanding of quantum gravity and high-dimensional physics.

📝String Theory

Dr. Kashyap’s expertise in string theory has significantly advanced the study of massive states and vacuum stability. His ongoing contributions to string theory continue to shape the discourse on fundamental physics. With his commitment to innovation, Dr. Kashyap is set to leave a lasting impact on string theory, ensuring its role as a cornerstone of modern theoretical physics.

Notable Publication

📝Closed superstring field theory and its applications

Authors: C. de Lacroix, H. Erbin, S. P. Kashyap, A. Sen, M. Verma

Journal: International Journal of Modern Physics A

Year: 2017

Citations: 133

📝Subleading soft theorem for multiple soft gravitons

Authors: S. Chakrabarti, S. P. Kashyap, B. Sahoo, A. Sen, M. Verma

Journal: Journal of High Energy Physics

Year: 2017

Citations: 65

📝Testing subleading multiple soft graviton theorem for CHY prescription

Authors: S. Chakrabarti, S. P. Kashyap, B. Sahoo, A. Sen, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 31

📝Amplitudes involving massive states using pure spinor formalism

Authors: S. Chakrabarti, S. P. Kashyap, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 13

📝Theta expansion of first massive vertex operator in pure spinor

Authors: S. Chakrabarti, S. P. Kashyap, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 12

📝Integrated massive vertex operator in pure spinor formalism

Authors: S. Chakrabarti, S. P. Kashyap, M. Verma

Journal: Journal of High Energy Physics

Year: 2018

Citations: 11

📝Surviving in a metastable de Sitter space-time

Authors: S. P. Kashyap, S. Mondal, A. Sen, M. Verma

Journal: Journal of High Energy Physics

Year: 2015

Citations: 9

Shaik Mohammed Ibrahim – Nano Fluids – Best Researcher Award 

Posted on by AMO Physics

Dr. Shaik Mohammed Ibrahim laid the foundation for his academic career with a strong emphasis on applied mathematics and fluid dynamics. He completed his PhD in 2010 from Sri Venkateswara University, Tirupathi, under the esteemed guidance of Prof. N. Bhaskar Reddy. His thesis, titled “Radiation Effects on Convective Heat and Mass Transfer Flows,” showcased his early dedication to exploring the complexities of fluid dynamics, heat transfer, and their real-world applications. His rigorous academic training set the stage for his future contributions to research and teaching in engineering and applied sciences.

💼 Professional Endeavors

Dr. Shaik Mohammed Ibrahim has an extensive teaching career spanning nearly two decades, with significant contributions to engineering education. He currently serves as an Associate Professor at Koneru Lakshmaiah Education Foundation (Deemed to be) University since June 2022, where he teaches B.Tech students. Prior to this, he worked as an Assistant Professor at GITAM (Deemed to be University), Vishakhapatnam, from 2015 to 2022. His leadership skills were evident during his tenure as Associate Professor and Head of the Department at Priyadarshini College of Engineering and Technology, Nellore, where he served from 2006 to 2015. His journey in academia began as a Lecturer at Seshachala Post Graduate Studies, Puttur, where he taught M.Sc and M.C.A students between 2004 and 2006.

🔬 Contributions and Research Focus

Dr. Ibrahim's research primarily focuses on fluid dynamics, heat and mass transfer, magnetohydrodynamics, non-Newtonian fluids, flows in porous media, and micropolar fluids. His extensive work in these areas has significantly contributed to the understanding of complex fluid behavior in various industrial and scientific applications. His expertise in nano fluids has opened new avenues in energy efficiency, thermal management, and biomedical applications. Additionally, his work extends to radiation effects in convective heat transfer, enhancing modern cooling techniques and aerospace engineering applications.

🌍 Impact and Influence

Dr. Ibrahim’s influence in academia is evident through his long-standing commitment to education and research. His membership in The Indian Society for Technical Education (ISTE) (No. LM 68410) reflects his dedication to fostering engineering education and professional development. His NPTEL Online Certification in "Transform Calculus and its Applications in Differential Equations" further highlights his commitment to continuous learning and expertise in mathematical modeling. His contributions have directly impacted students, researchers, and industry professionals who apply his findings in nano fluids and heat transfer research.

🏆Academic Cites

Dr. Ibrahim's scholarly contributions in nano fluids, fluid dynamics, and magnetohydrodynamics have been recognized through numerous academic citations. His research has been referenced in leading journals, showcasing the importance of his work in advancing theoretical and practical applications in heat transfer and fluid mechanics. His findings have helped shape contemporary research methodologies, offering innovative solutions to problems in energy systems, biomedical sciences, and aerospace engineering.

🌟 Legacy and Future Contributions

Looking ahead, Dr. Ibrahim aims to further expand his research in nano fluids and their role in enhancing energy efficiency and industrial applications. His future work will continue to bridge the gap between theoretical fluid mechanics and practical implementations, benefiting industries such as renewable energy, pharmaceuticals, and advanced cooling systems. As he continues to mentor students and collaborate with global researchers, his legacy as an educator and researcher will have a lasting impact on future generations of scientists and engineers.

📝Nano Fluids

Dr. Shaik Mohammed Ibrahim’s extensive research in nano fluids has led to groundbreaking advancements in thermal management and heat transfer applications. His continued exploration of nano fluids in magnetohydrodynamics and porous media is set to revolutionize industrial cooling systems and biomedical technologies. With a strong foundation in fluid mechanics and applied mathematics, his contributions to nano fluids research ensure lasting advancements in engineering and scientific domains.

Notable Publication

📝Melting Heat Transfer Effects on MHD Chemically Thermally Radiative Micropolar Fluid Flow towards Stretching Exponentially Sheet with Heat Sink/Source

Authors: S.M. Ibrahim, Shaik Mohammed; B. Lavanya; G. Dharmaiah; T. Sankar Reddy; P. Roja

Journal: CFD Letters

Year: 2025

Citations: 0

📝Investigation of heat and mass transfer in magnetohydrodynamic Williamson nanofluid flow over a nonlinear stretching surface with viscous dissipation and radiation effects: a numerical approach

Authors: S. Ramadevu, Syamala; P.V. Kumar, Prathi V.; S.M. Ibrahim, Shaik Mohammed; K. Jyothsna, Kanithi

Journal: Radiation Effects and Defects in Solids

Year: 2025

Citations: 0

📝A comprehensive study on Maxwell hybrid nanostructure and Maxwell nanostructure on 2D flow model over a stretching sheet with non-uniform heat generation/absorption and binary chemical reaction

Authors: K. Badak, Kirnu; R.P. Sharma, Ram Prakash; S.M. Ibrahim, Shaik Mohammed

Journal: Journal of Thermal Analysis and Calorimetry

Year: 2025

Citations: 0

📝Magneto-hydrodynamic mixed convection chemically rotating and radiating 3D hybrid nanofluid flow through porous media over a stretched surface

Authors: K. Bhargava, Katikala; S.M. Ibrahim, Shaik Mohammed; K. Raghunath, Kodi

Journal: Mathematical Modelling and Numerical Simulation with Applications

Year: 2024

Citations: 0

📝Transient flow and heat transfer characteristics of single-phase nanofluid past a stretching sheet under the influence of thermal radiation and heat source

Authors: Z.H. Khan, Zafar Hayat; K. Swain, K.; S.M. Ibrahim, Shaik Mohammed; W.A. Khan, Waqar Ahmed; Z. Huang, Zaitang

Journal: AEJ - Alexandria Engineering Journal

Year: 2024

Citations: 5

📝Radiative Chemically MHD Non-Newtonian Nanofluid Flow over an Inclined Stretching Sheet with Heat Source and Multi-Slip Effects

Authors: P.S. Kumari, Pennelli Saila; S.M. Ibrahim, Shaik Mohammed; P.V. Kumar, Prathi V.; G. Lorenzini, Giulio

Journal: International Journal of Computational Methods and Experimental Measurements

Year: 2024

Citations: 0

📝Impact of multiple slips and thermal radiation on heat and mass transfer in MHD Maxwell hybrid nanofluid flow over porous stretching sheet

Authors: Z.H. Khan, Zafar Hayat; W.A. Khan, Waqar Ahmed; S.M. Ibrahim, Shaik Mohammed; K. Swain, K.; Z. Huang, Zaitang

Journal: Case Studies in Thermal Engineering

Year: 2024

Citations: 10