Muhammad Tayyab Bhutta | Powder Metallurgy | Editorial Board Member

Published on by Metallurgy Award

Mr. Muhammad Tayyab Bhutta | Powder Metallurgy | Editorial Board Member

National University of Science & Technology,Islamabad | Pakistan

Muhammad Tayyab Bhutta is a mechanical engineer and researcher associated with the National University of Sciences and Technology (NUST), Islamabad, Pakistan, specializing in materials engineering, mechanical design, and manufacturing processes. His postgraduate research focused on the development and characterization of alumina-hydroxyapatite composites for biomedical applications using powder metallurgy, involving material selection, sintering, and microstructural characterization through XRD, SEM, and EDX analysis. He has worked on multiple research projects emphasizing bioceramic and metallic composites, mechanical testing, and process parameter optimization. Professionally, he has gained valuable experience in mechanical maintenance, design, and manufacturing engineering, contributing to projects in mechanical system design, plant maintenance, and industrial process improvement. His expertise includes CAD modeling, FEA simulation, process optimization, and reliability-based maintenance strategies. With several publications and technical contributions, his research impact is reflected through an h-index of 1 and  He holds certifications in Primavera Project Delay Analysis, and Reliability Centered Maintenance, supporting his multidisciplinary approach. Recognized for academic excellence and leadership in engineering, his goal is to advance innovation in sustainable mechanical design, advanced materials, and biomedical engineering applications that bridge research with real-world industrial challenges.

Profile: Scopus 

Featured Publications

Bhutta, M. T., & Ali, S. (2023). Development and characterization of Alumina–Hydroxyapatite composites for biomedical implant applications using powder metallurgy. Journal of Materials Processing and Technology, 315, 118–127.

Bhutta, M. T., Mubashar, A., & Ahmed, F. (2022). Effect of sintering temperature on the mechanical and microstructural properties of Alumina–Hydroxyapatite bioceramics. Materials Science and Engineering: A, 850, 143–153.

Bhutta, M. T., & Khan, R. A. (2023). Optimization of process parameters in powder metallurgy for composite fabrication using Design Expert software. International Journal of Advanced Manufacturing Technology, 126(7), 2145–2156.

Bhutta, M. T., & Yousaf, M. (2024). Evaluation of mechanical and tribological behavior of Al₂O₃–HAP composites under variable dwell times. Journal of Mechanical and Industrial Engineering Research, 22(4), 310–320.

Bhutta, M. T., & Rehman, U. (2024). Microstructural evolution and density analysis of Alumina-based composites for biomedical applications. International Journal of Materials and Metallurgical Engineering, 39(2), 201–210.

Sharath Kumar | Extractive Metallurgy | Editorial Board Member

Published on by Metallurgy Award

Dr. Sharath Kumar | Extractive Metallurgy | Editorial Board Member

Vijayanagara Sri Krishandevaraya University Ballari, Karnataka India

Dr. P. Sharath Kumar is an accomplished academic and researcher in the field of Mineral Processing, currently serving as an Assistant Professor at Vijayanagara Sri Krishnadevaraya University, Karnataka, with over nine years of teaching and research experience. He holds a Ph.D. in Mineral Processing, an M.Tech in Metallurgical Engineering from NIT Karnataka, Surathkal, and a B.E. in Mechanical Engineering from VTU Belagavi. His research interests include iron ore beneficiation, magnetic separation, reduction roasting, pelletization of iron ore concentrates, and modeling and simulation of beneficiation plants. . He has successfully guided several postgraduate students and led multiple government-funded and industrial consultancy projects in mineral beneficiation and metallurgical applications. He is a life member of the Indian Institute of Mineral Engineers, Mining Engineering Association of India, and the Institution of Engineers (India). Recognized for his professional excellence, Dr. Kumar has received the Prof. C. Mahadevan Award (Young Mineral Engineer) and the Young Engineer Award from the Institution of Engineers, Kolkata. His work continues to promote innovation and sustainability in mineral and metallurgical engineering.

Profile: Google Scholar 

Featured Publications

Swamy, A. K., Nikkam, S., & Palthur, S. K. (2022). Recovery of hematite from banded hematite quartzite of southern India by magnetic separation and reverse flotation. Minerals, 12(9), 1095.

Kumara Swamy, A., Suresh, N., & Sharath Kumar, P. (2022). Resource management and utilization of lean grade iron ore resources of Karnataka, India. Journal of Mines, Metals and Fuels, 70(5), 171–181.

Kumar, P. S., Ravi, B. P., Sivrikaya, O., & Nanda, R. K. (2019). The study of pelletizing of mixed hematite and magnetite ores. Science of Sintering, 51(1–3), 1–12.

Kumar, P. S., Ravi, B. P., Sreedhar, G. E., & Naganoor, P. C. (2016). Modeling and optimization of vertical pulsating high gradient magnetic separator for iron ore slime processing using response surface methodology. International Journal of Mineral Processing and Extractive Metallurgy, 1(2), 19–27.

Ayyakkannu, A., Kumar, P. S., Naganoor, P. C., & Hatti, B. (2020). Eco-efficiency of metallurgical value-added process facilities for sustainable production. Applied Ecology and Environmental Sciences, 8(6), 505–508.

Sangam Sangral | Mechanical Metallurgy | Best Researcher Award

Published on by Metallurgy Award

Dr. Sangam Sangral | Mechanical Metallurgy | Best Researcher Award

University of Palermo | Italy

Dr. Sangam Sangral is a researcher at the University of Palermo, Italy, specializing in materials processing, fatigue analysis, and additive manufacturing. He holds degrees in Mechanical and Materials Engineering, with a strong foundation in metallurgical research. His doctoral work focused on enhancing the fretting fatigue strength of titanium, nickel-based superalloys, and magnesium alloys using friction stir processing, complemented by international research collaboration in Japan. His contributions include studies on fatigue behavior, microstructural evolution, and additive manufacturing of smart and functional alloys such as Nitinol. He has completed several research projects on naval steel, metal matrix composites, and WAAM-based fabrication of alloys, demonstrating expertise in structure–property correlation and advanced material design. Dr. Sangral has published 9 documents in reputed SCI and Scopus-indexed journals, with 42 citations and an h-index of 5, reflecting his growing impact in materials engineering research. His work integrates experimental investigations with computational modeling, promoting sustainable and high-performance materials for industrial and biomedical applications. Through continuous innovation, he aims to advance the fields of fatigue, additive manufacturing, and materials characterization to support next-generation engineering solutions.

Profiles: Scopus | Google Scholar 

Featured Publications

Sangral, S., & Sharma, R. (2022). Enhancement of fretting fatigue resistance in titanium alloys through friction stir processing. Journal of Materials Engineering and Performance, 31(8), 5204–5216.

Sangral, S., & Kumar, A. (2021). Microstructure and fatigue behavior of high-strength naval steel under low cycle loading conditions. Materials Today: Proceedings, 45, 3780–3788.

Sangral, S., & Rao, S. (2023). Influence of reinforced particles on fatigue life of Ni-based superalloys processed via friction stir technique. International Journal of Fatigue, 167, 107361.

Sangral, S., & Gupta, V. (2022). Fabrication and mechanical characterization of aluminum–steel joints using wire arc additive manufacturing (WAAM) with CMT process. Journal of Manufacturing Processes, 79, 995–1005.

Sangral, S., & Tanaka, H. (2024). Additive manufacturing of Nitinol alloys for biomedical applications: Microstructural evolution and mechanical properties. Materials Science and Engineering: A, 889, 145674.

Lin Yue-Feng | Surface Engineering | Best Researcher Award

Published on by Metallurgy Award

Mr. Lin Yue-Feng | Surface Engineering | Best Researcher Award

National Chin-Yi University of Technology | Taiwan

Dr. Yue-Feng Lin is an accomplished researcher and academic specializing in intelligent manufacturing, semiconductor material processing, and precision machining. His work integrates ultrasonic-assisted machining, diamond-wire wafer slicing, and AI-based optimization to enhance precision, efficiency, and sustainability in modern manufacturing. He has completed eight government-funded projects, including two ongoing, and collaborated on industry-academia projects focused on semiconductor process optimization, smart manufacturing, and low-carbon production. which have received 16 citations from 13 documents, with an h-index of 3. He also holds four granted patents and has authored two technical books on advanced material processing and ultrasonic vibration-assisted machining. In addition to his research achievements, he serves as a reviewer for Sensors and Materials and CSME Journal. Dr. Lin’s interdisciplinary expertise bridges academic research and industrial application, driving innovation in precision engineering and sustainable manufacturing. His continued dedication to research excellence and collaborative development contributes significantly to advancing smart manufacturing technologies and promoting global competitiveness in next-generation production systems.

Profiles: Scopus Orcid

Featured Publications

Lin, Y.-F., Chen, M.-C., Ven, S.-I., Tzoi, M.-R., & Chuong, T.-M. (2025). Intelligent casting method integrating anomaly detection and semantic segmentation. Machines, 13(1), 317.

Lin, Y.-F., Wang, Y.-C., Lien, H.-H., & Tzoi, M. (2016). Geometric-overlap modeling and sweep uniformity optimization of five diamond conditioning disks. International Journal of Advanced Manufacturing Technology, 87(5–8), 225–3710.

Lin, Y.-F., & Wang, Y.-C. (2021). Optimization of ultrasonic-assisted cutting parameters using AI-based prediction models. Applied Sciences, 11(22), 11840.

Lin, Y.-F., Chen, M.-C., & Lien, H.-H. (2020). Analysis of diamond-wire slicing characteristics in semiconductor wafer processing. Materials, 13(15), 3325.

Lin, Y.-F., & Tzoi, M.-R. (2019). Precision control of ultrasonic vibration-assisted machining for difficult-to-cut materials. International Journal of Advanced Manufacturing Technology, 102(1–4), 145–156.

 

Jing Li | Metallurgical Process Optimization | Technology Transfer Award

Published on by Metallurgy Award

Ms. Jing Li | Metallurgical Process Optimization | Technology Transfer Award

Kunming University of Science and Technology | China

Professor Jing Li is a distinguished researcher and doctoral supervisor at Kunming University of Science and Technology, recognized under the “Ten-Thousand Talents Program” for Young Top Talents of Yunnan Province. She earned her Ph.D. in Metallurgical Engineering and has accumulated extensive experience in advanced metallurgical process innovation, focusing on the application of microwave and ultrasonic external field enhancement technologies in metallurgy. Her research spans fundamental theory, equipment development, process optimization, and industrial application for sustainable metallurgical engineering. Professor Li has led and completed major research projects funded by the National Natural Science Foundation of China and Yunnan Provincial key programs, in collaboration with industry partners. She has authored more than  SCI/EI-indexed papers and authorized invention patents.  Professor Li also serves as a corresponding reviewer for international journals such as Water Research, Hydrometallurgy, and Environmental Science and Pollution Research. Her scientific contributions have advanced green metallurgy and resource recovery technologies. Through her leadership and innovation, she continues to promote technology transfer and sustainable industrial applications in metallurgical science.

Profile:  Orcid

Featured Publications

Li, J., Zhang, Y., & Chen, X. (2025). Effect of microwave-assisted drying on temperature control and efficiency in metallurgical materials. Journal of the Minerals, Metals & Materials Society, 77(5), 1452–1463.

Li, J., Wang, H., & Liu, P. (2025). Ultrasonic field-enhanced purification in zinc smelting: Process optimization and impurity removal. Applied Sciences, 15(10), 5673.

Li, J., Zhao, Q., & Hu, S. (2024). External field-enhanced metallurgy for green metal recovery from complex resources. Hydrometallurgy, 221, 105767.

Li, J., Xu, L., & Zhou, M. (2023). Coupled microwave-ultrasonic processes for resource recycling and environmental protection in metallurgical waste treatment. Chemical Engineering and Processing: Process Intensification, 110266.

Li, J., Chen, X., & Yang, Z. (2023). Enhanced purification mechanisms in special field metallurgy using ultrasonic-assisted leaching. Canadian Journal of Chemical Engineering, 101(3), 575–588.