Dr. Michał Hajos | Materials Engineering | Best Researcher Award

University of Agriculture in Krakow, Poland.

Michal Hajos is a skilled academic and researcher currently working at the University of Agriculture in Krakow, Poland. With a strong foundation in metallurgy and extensive experience in industrial research, Hajos has dedicated his career to exploring innovative solutions in material science, combustion processes, and plant-based material research. He has worked on numerous industrial and academic projects, contributing significantly to both the research and development sectors. His research interests include the study of combustion and drying processes and the exploration of green methods for nanoparticle production.

Profile

Scopus

Education 🎓

Dr. Michał Hajos holds a PhD in Metallurgy from AGH University in Krakow (2008–2014), with a dissertation on "Physicochemical parameters of the electrochemical process for the production of zinc oxide nanoparticles." He also earned a Master of Science in Metallurgy from the same institution (2002–2008), where his thesis focused on binders in molding sands. Additionally, he completed his Environmental Protection Technician qualification at Zespół Szkół Chemicznych in Krakow (1995–2000), researching the use of industrial waste as alternative fuels in the cement industry.

Work Experience 💼

Dr. Michał Hajos is currently an Assistant at the University of Agriculture in Krakow (2022–present), focusing on research and teaching in mechanical engineering and agrophysics, with expertise in material science and thermodynamics. He served as Head of Executive at CBR Rock Master (2021–2022), overseeing R&D, production planning, and product certification. Prior to that, he was a Laboratory Analyst (2019–2021) at the same company, specializing in designing and testing prototypes for height safety systems. Dr. Hajos also worked as a Process Engineer at NYCZ Intertrade (2016–2018), leading nickel recovery processes from galvanic waste. Earlier, he contributed as a Research Assistant and Lecturer at AGH University of Science and Technology (2012–2015), designing measurement stands and conducting research for shale gas extraction projects.

Research Interests 🔬

Dr. Michał Hajos focuses on the study of combustion and drying processes 🔥💧, aiming to optimize energy efficiency and material properties.

Physico-Chemical Properties of Plant-Based Materials 🌿

He investigates the physico-chemical properties of plant-based materials, exploring sustainable alternatives for various industrial applications.

Green Nanoparticle Production 🌱🔬

A significant aspect of his research is the development of green methods for nanoparticle production, striving to create eco-friendly technologies for the future.

Achievements 🏆

Third Degree Award in the "Technician 2000" competition (2000)
For his thesis on alternative fuels for the cement industry.

Patent in Nickel Recovery Process (2014)
Involved in the patenting process for the method of manufacturing molds and cores in smelting technologies.

Multiple Conference Contributions (2008–2013)
Organized and participated in various national and international conferences, contributing to both research dissemination and academic development.

Selected Publications 📚

Size Distribution of Zinc Oxide Nanoparticles Depending on the Temperature of Electrochemical Synthesis
Hajos, M., Starowicz, M., Brzychczyk, B., Basista, G., Francik, S.
Materials, 2025, 18(2), 458
Focus: This study investigates how the temperature during electrochemical synthesis affects the size distribution of zinc oxide nanoparticles.

Prediction of Brake Pad Wear of Trucks Transporting Oversize Loads Based on the Number of Drivers’ Braking and the Load Level of the Trucks—Multiple Regression Models
Basista, G., Hajos, M., Francik, S., Pedryc, N.
Applied Sciences (Switzerland), 2024, 14(13), 5408
Focus: This article uses multiple regression models to predict brake pad wear in trucks transporting oversize loads.

Citations: 1

Modeling the Drying Process of Onion Slices Using Artificial Neural Networks
Francik, S., Łapczyńska-Kordon, B., Hajos, M., Zawiślak, A., Francik, R.
Energies, 2024, 17(13), 3199
Focus: The study explores the application of artificial neural networks to model the drying process of onion slices.

Cohesion and Adhesion Properties of Modified Water Glass with Colloidal Solutions of ZnO
Smyksy, K., Kmita, A., Hutera, B., Hajos, M., Starowicz, M.
Metalurgija, 2014, 53(4), pp. 459–462
Focus: The article discusses the cohesion and adhesion properties of modified water glass combined with colloidal solutions of zinc oxide.

Citations: 5

Morphology and Structure of ZnO Nanoparticles Produced by Electrochemical Method
Stypuła, B., Kmita, A., Hajos, M.
Medziagotyra, 2014, 20(1), pp. 3–9
Focus: This paper examines the morphology and structure of zinc oxide nanoparticles produced through an electrochemical method.

Mr. Yi Cui | Materials Science | Best Researcher Award

Stanford University, United States.

Mr. YI Cui is a Ph.D. candidate in Materials Science and Engineering at Stanford University. He holds a B.S. in Chemistry from the University of Science and Technology of China (USTC). YI's research delves into the cutting-edge fields of materials science, particularly focusing on phase segregation dynamics in mixed halide perovskites and twisted epitaxial growth of gold nanodiscs in 2D materials. His innovative work has earned him recognition in the field of nanotechnology and energy materials.

Education 🎓

YI Cui is currently pursuing a Ph.D. in Materials Science and Engineering at Stanford University, California, under the guidance of Professors Yi Cui and Bob Sinclair (Jan. 2021 - Jun. 2025). Prior to this, he completed a Bachelor of Science in Chemistry at the University of Science and Technology of China (USTC) in Hefei, where he was part of the prestigious Special Class for the Gifted Young, Department of Chemical Physics (Aug. 2016 - Jun. 2020).

Experience 💼

YI Cui has worked on groundbreaking research projects, including studying phase segregation dynamics in mixed halide perovskites using advanced cryo-EM techniques and pioneering twisted epitaxial growth methods for nanodiscs in 2D materials. His projects span from energy materials to nanotechnology, making significant contributions to understanding the behavior of materials at the atomic level. He has gained extensive research experience through collaborations with top professors at Stanford and USTC, focusing on the development of innovative materials for energy applications.

Research Interests 🔬

Phase segregation dynamics in mixed halide perovskites, particularly through cryogenic electron microscopy.

Twisted epitaxial growth of gold nanodiscs within twisted bilayer 2D materials, such as molybdenum disulfide.

Investigation of advanced materials for energy storage, such as lithium metal batteries and solid-state electrolytes.

Developing novel techniques for characterizing and manipulating materials at the atomic and nanoscale.

Publications Top Notes📚

Design Principles of Artificial Solid Electrolyte Interphases for Lithium-Metal Anodes, Cell Reports Physical Science, 2020
Contributors: Yu Zhiao, Cui Yi, Bao Zhenan. Link

Transient Voltammetry with Ultramicroelectrodes Reveals the Electron Transfer Kinetics of Lithium Metal Anodes, Adv. Energy Lett., 2020, Contributors: Boyle David, Kong Xian, Pei Allen, Rudnicki Paul, Shi Feifei, Huang William, Bao Zhenan, Qin Jian, Cui Yi. Link

Atomic-level insights into strain effect on p-nitrophenol reduction via Au@Pd core-shell nanocubes as an ideal platform
Journal of Catalysis, 2020-01-01, Contributors: Cui, Yi; Ma, Kaibo; Chen, Zhao; Yang, Jinlong; Geng, Zhigang; Zeng, Jie. Link

Dynamic Structure and Chemistry of the Silicon Solid-Electrolyte Interphase Visualized by Cryogenic Electron Microscopy, Matter, 2019, Contributors: Huang William, Wang Jiangyan, Braun R Michael, Zhang Zewen, Li Yuzhang, Boyle T David, McIntyre C Paul, Cui Yi. Link