Mohammad Reza Toroghinejad toroghi@iut.ac.ir Google Scholar Office Department of Materials Engineering, Isfahan University of Technology, Isfahan 84156-83111, Iran Phone +98 (31) 33915726 Fax +98 (31) 33915726 Positions Professor of Materials Engineering Research Interests Crystallographic Texture of Materials High Entropy Alloys and Materials Sever Plastic Deformation Failure Analysis Composite Metal Forming Mohammad Reza Toroghinejad type: Journal Title Conference / Journal Date Emergence of hierarchical textural pattern in a Fe-rich FeMnNiCr high-entropy alloy: Identification of Goss texture MATERIALS CHARACTERIZATION 2026-02 Static recrystallization and texture evolution in multiphase FeCrCuMnNi high-entropy alloys: Mechanisms and strength-ductility synergy JOURNAL OF ALLOYS AND COMPOUNDS 2025-10 Evolution of Rotated Cube Texture and Its Influence on the Mechanical and Fracture Properties of Al/Ti/Alumina Composites Fabricated via ARB Metallography Microstructure and Analysis 2025-09 Data-driven prediction of ultimate tensile strength in low alloy steel: A machine learning approach COMPUTATIONAL MATERIALS SCIENCE 2025-08 Characterization of dynamic recrystallization and development of a processing map during hot deformation of FeCoCrNi high-entropy alloy Journal of Materials Research and Technology-JMR and T 2025-06 Enhancing microstructure and mechanical properties of FeNi1.5CrCu0.5 high-entropy alloy through precipitation treatment and cold rolling Results in Materials 2025-06 Effect of prior austenite grain size on strength-ductility trade-off, phase evolution, and fracture behavior in a fully austenitizated QP steel: Insights into TRIP behavior Journal of Materials Research and Technology-JMR and T 2025-06 Microstructural evolution of Bi-layered NiCrAlY/CeO2 - Graphene Nanoplatelet coatings by air plasma spray and spark plasma sintering Heliyon 2025-03 Enhancement of strength and toughness of multicomponent Al-alloy via nano twining and nano precipitate through heat treatment Results in Engineering 2025-03 Investigation of failure mechanism in tensile loading of Cu-AISI4140 steel joints fabricated by spark plasma welding Journal of Materials Research and Technology-JMR and T 2025-01