Asif Muzaffar | Artificial Intelligence and Machine Learning | Research Excellence Award

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Dr. Asif Muzaffar | Artificial Intelligence and Machine Learning | Research Excellence Award

Teaching Fellow | Birmingham City University | United Kingdom

Dr. Asif Muzaffar is a recognized researcher in Operations and Supply Chain Management, known for advancing quantitative modelling, sustainable operations, and digital supply chain innovation. With 816 citations, 45 documents, an h-index of 16, and an i10-index of 17, his scholarly influence is reflected through publications in leading journals, including Sustainable Production and Consumption, Sustainable Development, Operations Management Research, Technological Forecasting & Social Change, International Journal of Disaster Risk Reduction, and the Journal of Services Marketing. His research portfolio encompasses 21 peer-reviewed journal papers, multiple conference contributions, and ongoing works addressing dynamic pricing, newsvendor models, sustainable procurement, and consumer behavior in digital environments. Dr. Asif Muzaffar’s contributions span supply chain contracts, institutional pressures, triple bottom line sustainability, rebate mechanisms, and technology-enabled service innovations such as AR/VR. His work often integrates simulation modelling, optimization, and game-theoretic frameworks to generate actionable insights for resilient, low-carbon, and digitally enabled supply chain systems. He has disseminated his findings at major international conferences, contributing evidence-based perspectives on biased decision-making, rebate coordination, and supply chain optimization. His research leadership extends to mentoring graduate research, shaping sustainable supply chain methodologies, and contributing as a reviewer for high-impact journals including Technological Forecasting & Social Change and Sustainable Development. Through these scholarly contributions, Dr. Asif Muzaffar has established himself as an influential voice in contemporary sustainable operations and supply chain research.

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Featured Publications

Ibrahim Aromoye | Artificial Intelligence and Machine Learning | Editorial Board Member

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Mr. Ibrahim Aromoye | Artificial Intelligence and Machine Learning | Editorial Board Member

Graduate Research Assistant | Universiti Teknologi PETRONAS | Malaysia

Mr. Ibrahim Aromoy is a promising researcher in Electrical and Electronic Engineering with a growing scholarly footprint in hybrid UAV systems, artificial intelligence, and intelligent surveillance technologies. His research is centered on the development of a Pipeline Inspection Air Buoyancy Hybrid Drone, a novel UAV concept that combines lighter-than-air and heavier-than-air technologies to improve flight endurance, stability, and inspection efficiency. By integrating deep learning–based object detection architectures into UAV platforms, his work advances real-time pipeline monitoring, anomaly identification, and autonomous decision-making for industrial applications. His contributions span AI-driven automation, robotics, swarm intelligence, energy-efficient IoT systems, and 5G-enabled surveillance technologies. He has authored several research papers in reputable international journals and conferences, including publications in IEEE Access, Neurocomputing, and Elsevier venues. These works address UAV reconnaissance, transformer-based detection models for pipeline integrity assessment, and optimization frameworks inspired by swarm behavior. His research output reflects measurable scholarly influence, with 15 Scopus citations, 7 indexed documents, and an h-index of 2. Mr. Ibrahim Aromoy has participated in multiple research and development projects, contributing to UAV design, embedded hardware integration, machine learning pipelines, and cyber-secure control systems. His work in hybrid drone architecture and automated surveillance has been supported by competitive institutional funding, reinforcing the technological relevance and innovation potential of his research. His scientific contributions extend beyond publications to academic service. He serves as a peer reviewer for high-impact journals such as IEEE Access and Results in Engineering, supporting the advancement of rigorous research dissemination in engineering and applied sciences. His expertise also includes AI vision systems, OpenCV-based automation, and embedded cybersecurity applications for unmanned systems, further strengthening his interdisciplinary research profile. Mr. Ibrahim Aromoy has been recognized with research-focused scholarships and academic distinctions that support his ongoing work in UAV innovation and intelligent automation. Through his integrated expertise in UAV engineering, deep learning, and intelligent inspection systems, he continues to contribute meaningfully to the evolution of smart surveillance, autonomous robotics, and AI-augmented engineering technologies.

Profiles: Scopus | ORCID | Google Scholar | ResearchGate | Web of Science

Featured Publications

1. Aromoye, I., Lo, H., Sebastian, P., Ghulam, E., & Ayinla, S. (2025). Significant advancements in UAV technology for reliable oil and gas pipeline monitoring. Computer Modeling in Engineering & Sciences, 142(2), 1155.

2. Aromoye, I. A., Hiung, L. H., & Sebastian, P. (2025). P-DETR: A transformer-based algorithm for pipeline structure detection. Results in Engineering, 26, 104652.

3. Zahid, F., Ali, S. S. A., & Aromoye, I. A. (2025). Exploring the potential benefits and overcoming the constraints of virtual and augmented reality in operator training. Transportation Research Procedia, 84, 625–632.

4. Mansoor, Y., Zahid, F., Azhar, S. S., Rajput, S., & Aromoye, I. A. (2025). Energy-efficient solar water pumping: The role of PLCs and DC-DC boost converters in addressing water scarcity. Transportation Research Procedia, 84, 681–688.

5. Zahid, F., Rajput, S., Ali, S. S. A., & Aromoye, I. A. (2025). Challenges and innovations in 3D object recognition: The integration of LiDAR and camera sensors for autonomous applications. Transportation Research Procedia, 84, 618–624.

Amir R. Masoodi | Artificial Intelligence and Machine Learning | Editorial Board Member

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Assist. Prof. Dr. Amir R. Masoodi | Artificial Intelligence and Machine Learning | Editorial Board Member

Assistant Professor | Ferdowsi University of Mashhad | Iran

Assist. Prof. Dr. Amir R. Masoodi is a highly accomplished structural engineering researcher whose work spans nonlinear mechanics, composite structures, vibration analysis, finite element modeling, and advanced material systems. With 1,789 Scopus citations, 77 publications, and an h-index of 29, he has established a strong international research footprint in computational mechanics, structural stability, soil–structure interaction, wave propagation, and multiscale modeling of advanced composites. His research contributions include developing novel finite element formulations for beams, plates, and shells, particularly for functionally graded materials (FGMs), carbon nanotube (CNT)-reinforced composites, graphene nanocomposites, and porous structural systems. Assist. Prof. Dr. Amir R. Masoodi’s work on nonlinear dynamic analysis, thermal–mechanical coupling, shell instability, and multiscale behavior of nano-engineered materials has been widely cited and influential in advancing modern structural design methodologies. He has published extensively in leading journals such as Composite Structures, Engineering Structures, Mechanics of Advanced Materials and Structures, Aerospace Science and Technology, Scientific Reports, and Applied Sciences. His publications address cutting-edge topics including vibration of hybrid nano-reinforced shells, multiscale characterization of nanocomposites, nonlinear buckling behavior of tapered beams, thermomechanical modeling of composite cables, and smart materials incorporating shape-memory alloys. Assist. Prof. Dr. Amir R. Masoodi has presented his findings at numerous international conferences and contributed several book chapters, including work on nanofillers and thermal properties in advanced materials. His research output extends to R&D projects, predictive modeling, and computational innovations in structural and nano-engineered systems. He has been recognized with multiple distinguished researcher awards, national elite recognitions, and research excellence honors. His expertise is further reflected in his editorial board memberships and contributions as a reviewer for reputable journals. Overall, Assist. Prof. Dr. Amir R. Masoodi’s research stands at the intersection of computational mechanics, smart materials, and multiscale structural engineering, offering impactful advances for next-generation civil, mechanical, and aerospace systems.

Profiles: Scopus | ORCID | Google Scholar | Sci Profiles | Web of Science

Featured Publications

1. Sobhani, E., Masoodi, A. R., & Ahmadi-Pari, A. (2021). Vibration of FG-CNT and FG-GNP sandwich composite coupled conical–cylindrical–conical shell. Composite Structures, 273, 114281.

2. Sobhani, E., Masoodi, A. R., Civalek, O., & Ahmadi-Pari, A. R. (2021). Agglomerated impact of CNT vs. GNP nanofillers on hybridization of polymer matrix for vibration of coupled hemispherical–conical–conical shells. Aerospace Science and Technology, 120, 107257.

3. Rezaiee-Pajand, M., Sobhani, E., & Masoodi, A. R. (2020). Free vibration analysis of functionally graded hybrid matrix/fiber nanocomposite conical shells using multiscale method. Aerospace Science and Technology, 105, 105998.

4. Rezaiee-Pajand, M., Arabi, E., & Masoodi, A. R. (2019). Nonlinear analysis of FG-sandwich plates and shells. Aerospace Science and Technology, 87, 178–189.

5. Rezaiee-Pajand, M., Masoodi, A. R., & Mokhtari, M. (2018). Static analysis of functionally graded non-prismatic sandwich beams. Advances in Computational Design, 3(2), 165–190.

Chao Zhang | Machine Learning | Best Researcher Award

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Prof. Chao Zhang | Machine Learning | Best Researcher Award

Professor at Shanghai University, China.

Prof. Chao Zhang is a distinguished mechanical engineer and academic based at Shanghai University. With a career spanning over four decades, Prof. Zhang has made pioneering contributions to tribology, engine wear modeling, and lubrication science. His expertise lies in the integration of quantum chemical molecular dynamics, artificial intelligence, and machine learning into mechanical systems analysis, particularly in the development of kinetic models and digital twins. He has collaborated with renowned experts such as Profs. H.S. Cheng and Qian Wang during his tenure as a senior research associate at Northwestern University, USA (1997–2002), and has held professorships at Tongji University, Shanghai University, and Kunming University of Science and Technology. Prof. Zhang’s research has played a transformative role in understanding tribocorrosion, antiwear mechanisms, and mechanochemical processes in engine components. His innovative work applies computational intelligence and quantum-level simulation to practical engineering problems, improving lubrication performance, predicting scuffing failures, and optimizing engine durability. He has led multiple high-impact national and industrial projects, contributing significantly to both theoretical and applied tribology. Prof. Zhang is also involved in industry-academic partnerships, editorial boards, and international scientific collaborations. His career embodies the intersection of advanced theory, simulation, and engineering practice, making him a leader in mechanical engineering innovation.

Publication Profile

Scopus

Education

Prof. Chao Zhang holds three advanced degrees in Mechanical Engineering. He earned his Bachelor of Arts (B.A.) in Mechanical Engineering from Shanghai Railway University in 1983, where he laid the foundation for his lifelong commitment to mechanical systems design and analysis. He pursued a Master of Science (M.S.) degree at the Shanghai Internal Combustion Engine Research Institute, graduating in 1989. His master’s research centered on internal combustion engine performance and lubrication, paving the way for his deeper exploration into tribology and wear mechanisms. Prof. Zhang completed his Doctor of Philosophy (Ph.D.) in Mechanical Engineering at Shanghai University in 1997. His doctoral work focused on advanced wear modeling and lubrication processes in engine systems. In addition to his formal education, Prof. Zhang expanded his research acumen as a senior research associate at Northwestern University from 1997 to 2002, working under the mentorship of tribology pioneers Prof. H.S. Cheng and Prof. Qian Wang. His education has equipped him with a robust theoretical foundation and practical expertise in mechanics, materials, and computational modeling. The interdisciplinary and global nature of his academic background uniquely positions Prof. Zhang to contribute significantly to high-impact, cutting-edge engineering research and education.

Professional Experience

Prof. Chao Zhang has had a remarkable professional journey across academia and international research institutions. After completing his Ph.D. in 1997, he joined Northwestern University (USA) as a senior research associate, working with Profs. H.S. Cheng and Qian Wang on pioneering tribological studies. From 1997 to 2002, he contributed to foundational research in tribocorrosion, lubrication modeling, and engine wear, integrating both experimental and computational approaches. Returning to China, Prof. Zhang held faculty positions at several leading institutions including Tongji University, Kunming University of Science and Technology, and his current post at Shanghai University. As a professor, he has led numerous research projects funded by national foundations and industry sponsors. He has supervised postgraduate students, developed novel tribological models, and built cross-disciplinary collaborations in mechanical engineering, materials science, and computational chemistry. Prof. Zhang’s expertise in applying quantum molecular dynamics and AI to wear modeling has earned him recognition across scientific communities. His work has contributed significantly to tribology research in internal combustion engines, scuffing failure analysis, and antiwear film formation. Throughout his career, Prof. Zhang has demonstrated academic leadership, innovation in applied mechanics, and a commitment to developing next-generation engineering solutions.

Research Interest

Prof. Chao Zhang’s research interests lie at the confluence of mechanical engineering, computational chemistry, and artificial intelligence. His primary focus is on tribology, particularly in the modeling of engine wear, boundary lubrication, and tribocorrosion processes. He has developed advanced multi-phase and multi-scale models that utilize quantum chemical molecular dynamics (QCMD), machine learning, and electron-phonon coupling to simulate friction, wear, and lubrication at the molecular level. His work also investigates scuffing mechanisms, offering predictive insights through kinetic models and scuffing failure mapping techniques. Prof. Zhang has a strong interest in mechanochemical processes, especially in relation to antiwear additive behaviors, lubricant chemistry, and film formation under operational engine conditions. His digital twin frameworks for tribological systems apply big data analytics and cloud computing for real-time simulation and optimization. Additional areas of interest include boundary film behavior, nano-tribology, AI-assisted diagnostics, and advanced simulation of component surface interactions. His interdisciplinary approach integrates physics-based modeling, chemical reaction kinetics, and machine learning algorithms, pushing the boundaries of traditional mechanical engineering and offering valuable insights for industries such as automotive, energy, and materials engineering.

Research Skills

Prof. Chao Zhang possesses a unique blend of research skills that merge classical mechanical engineering with cutting-edge computational techniques. His expertise in quantum chemical molecular dynamics (QCMD) enables him to simulate tribological interactions at atomic and molecular scales, allowing for a deeper understanding of wear and lubrication mechanisms. He is proficient in developing multi-scale models and applying machine learning (ML) algorithms for pattern recognition, prediction, and optimization in tribological systems. Prof. Zhang also has advanced skills in digital twin development, where he uses big data and cloud computing to model the real-time behavior of engine components under tribocorrosive conditions. His methodological toolkit includes SOL (state-of-lubrication) modeling, electron-phonon interaction theory, reaction kinetics modeling, and mechano-chemical simulation techniques. He is adept at integrating artificial intelligence (AI) with physics-based simulations to derive hybrid models that offer high accuracy and predictive capability. Additionally, Prof. Zhang’s experimental experience in tribometry and engine component testing complements his theoretical models, resulting in comprehensive and validated research outputs. His cross-domain skills enable him to bridge engineering applications with fundamental science, making his contributions innovative and impactful across both academic and industrial sectors.

Awards and Honors

Prof. Chao Zhang has received numerous accolades in recognition of his outstanding contributions to mechanical engineering and tribological research. While specific award names are not detailed in the provided material, his career achievements reflect a high level of scholarly and industrial impact. His tenure at Northwestern University and subsequent professorships at major Chinese universities are testaments to his international reputation and academic excellence. The research projects led by Prof. Zhang have been consistently funded by prestigious national science foundations and industry stakeholders, reflecting the high relevance and quality of his work. His interdisciplinary methods—integrating quantum simulation, machine learning, and real-time modeling—have earned him a respected place in tribology and lubrication science communities. He is frequently invited to collaborate on high-impact projects and contribute to strategic research in engine wear reduction and surface engineering. Prof. Zhang’s work on scuffing failure mapping and digital twin development for tribocorrosion systems has also been featured in leading engineering forums. While further documentation is needed for a comprehensive list, it is evident that Prof. Zhang’s career is distinguished by innovation, academic leadership, and impactful contributions to tribological science.

Author Metrics

  • Total publications: 24 (1995–2025)
  • Total citations: 8,470 (as of June 2025)
  • h‑index: 51
  • i10‑index: 60

Publications Top Notes

📘 Multi‑phase and multi‑scale engine wear modeling via quantum chemical molecular dynamics and machine learning

  • Authors: Zhang, C.

  • Title: Multi‑phase and multi‑scale engine wear modeling via quantum chemical molecular dynamics and machine learning: A theoretical framework

  • Journal: Wear, Volume 571, Article 205771

  • Date: 15 June 2025

📘 Lubricant–Chemistry Kinetic Model of Antiwear Film Formation by Oil Additives using SOL, QM MD, and machine learning

  • Authors: Zhang, C.

  • Title: Lubricant–Chemistry Kinetic Model of Antiwear Film Formation by Oil Additives using SOL, QM MD, and machine learning

  • Conference: STLE 2023 Annual Meeting Digital Proceedings

  • Year: 2023

📘 Scuffing behavior of piston‑pin bore bearing in mixed lubrication

  • Authors: Zhang, C.

  • Title: Scuffing behavior of piston‑pin bore bearing in mixed lubrication

  • Publisher: Springer

  • Year: 2022

  • Published Online: 30 March 2022

📘 Quantum chemical study of mechanochemical reactive mechanisms of engine oil antiwear additives

  • Authors: Zhang, C.

  • Title: Quantum chemical study of mechanochemical reactive mechanisms of engine oil antiwear additives

  • Conference: Proceedings of I4SDG Workshop 2021, MMS 108, pp. 1–9

  • Year: 2022 (Proceedings published 2022)

📘 Scuffing factor and scuffing failure mapping

  • Authors: Zhang, C.

  • Title: Scuffing factor and scuffing failure mapping

  • Conference: Proceedings of the 2nd World Congress on Internal Combustion Engine, April 21–24, 2021, Jinan, China

  • Year: 2021

Conclusion

Prof. Chao Zhang is an eminent researcher and educator in the field of mechanical engineering, with a distinguished career characterized by innovation, interdisciplinary research, and academic leadership. Through his pioneering work in tribology, engine wear modeling, and lubrication science, Prof. Zhang has bridged the gap between molecular-level simulations and real-world engineering applications. His integration of quantum chemical molecular dynamics, machine learning, and cloud-based digital twins has opened new pathways in tribocorrosion analysis, scuffing prediction, and antiwear film development. With decades of experience in both the United States and China, he has nurtured academic collaborations and guided research with significant scientific and industrial impact. His ability to combine theoretical insight with practical application exemplifies the future of smart mechanical systems and intelligent design frameworks. Prof. Zhang’s contributions extend beyond individual research projects to shaping the next generation of engineering solutions and researchers. As a leader in mechanical science and tribology, his work continues to influence engine design, lubricant formulation, and component life prediction globally. Prof. Zhang’s dedication to excellence, research rigor, and scientific advancement positions him as a valuable asset to both academia and industry in addressing complex mechanical and material challenges of the modern era.