Post-Doctoral Researcher | Energy Storage & Advanced Materials
I am a Post-Doctoral Fellow at Iran University of Science and Technology and hold a Ph.D. in Materials Science and Engineering from the University of Tabriz. My research focuses on advanced materials for energy and sustainable technologies.
My main research interests include friction spot joining and welding of dissimilar materials, electrochemical hydrogen storage, lithium-ion batteries, and energy storage systems. I am particularly interested in developing novel functional materials and structures to improve the performance, efficiency, and sustainability of next-generation energy storage devices.
Research interest
Electrochemical hydrogen storage and storage mechanisms
Lithium-ion batteries and next-generation energy storage systems
2D and 3D functional materials (graphene-based and metal oxide composites)
Friction spot welding and solid-state joining of dissimilar materials
Sustainable and renewable energy materials
Advanced characterization and electrochemical testing
About me
I am a PostDoctoral Fellow at Iran University of Science and Technology and a Ph.D. candidate in Materials Science and Engineering at the University of Tabriz. My doctoral research is conducted within the Department of Materials Science at the School of Mechanical Engineering.
My research focuses on advanced joining techniques and energy storage technologies, with particular emphasis on friction spot welding, brazing, and solid-state joining of dissimilar materials.
In parallel, I work on the synthesis and development of advanced functional materials for electrochemical energy storage and sustainable energy systems, including ٍ Electrochemical hydrogen storage, supercapacitors, and lithium-ion batteries.
I am supervised by Prof. Hossein Aghajani and Prof. Shahab Khameneh Asl, with advisory support from Prof. Seyed Morteza Masoudpanah and Prof. Marek Wojnicki. I also collaborate closely with Prof. Mahdi Azizieh.
Research & Projects
Development of 3D graphene-based materials for electrochemical hydrogen storage
Synthesis of vanadium-based oxides for batteries and supercapacitors
Friction spot brazing and welding of steel, titanium, and aluminum systems
Assembly and testing of lithium-ion battery cells using glove box systems
Selected Publications
Electrochemical Hydrogen Storage of 3D Graphene Foam Composited with Vanadium Oxide, Energy Storage, 2025
Carbon Materials in Electrochemical Hydrogen Storage and Their Mechanisms, MDPI, 2025
Friction Spot Brazing of Stainless Steel to Titanium Using Aluminum Foil, Materials Research Express, 2022
(Full publication list available on Google Scholar)
Patents
Methods for Fabricating a Three-Dimensional Energy Storage Foam Based on Graphene Oxide/Vanadium Oxide Composite
International Patent Application (PCT)
Application Number: PCT/IB2024/060298
This patent presents a novel method for fabricating three-dimensional graphene oxide/vanadium oxide composite foams designed for advanced energy storage applications. The developed structure enhances electrochemical performance and provides improved pathways for ion transport, making it suitable for hydrogen storage and battery-related technologies.
Book Chapter & Reviews
Study on Nanostructured Coatings: Coating Methods and Characterization
Book Chapter, Nanotechnology Series (Multi-volume Set: Vols. 1–10)
Studium Press LLC, 2013.
This book chapter reviews advanced nanostructured coating techniques and characterization methods, with a focus on structure–property relationships and functional performance of engineered surfaces.
Skills & Facilities, Experimental & Characterization
SEM, AFM, XRD, XPS, and TEM
Electrochemical tests (CV, EIS, GCD)
Glove box battery assembly
Scanning Electron Microscopy Operator
Software
Origin, X’Pert HighScore, ZView
FactSage, SolidWorks, LaTeX
3 Dimensional Graphene Foam
Lithium Primary Ion Battery 2032
