Dr. Jae Joong Ryu

Associate Professor
Dr. Jae Joong Ryu - profile photo

Dr. Jae Joong Ryu

Associate Professor

Rayen School of Engineering

Moser Hall 2545

phone: (330) 941-2396

jjryu@ysu.edu

  • Intellectual Contributions
    • 2022

      "Thermal Stress Characteristics of Dissimilar Joints Joining Ti-64 and CCM via Linear Friction Welding"

      Energies, volume 15, issue 15, p. 5588

    • 2022

      "Sliding Corrosion Fatigue of Metallic Joint Implants: A Comparative Study of CoCrMo and Ti6Al4V in Simulated Synovial Environments"

      Lubricants, volume 10, issue 4, p. 65

    • 2022

      "Heat Transfer and Structural Characteristics of Dissimilar Joints Joining Ti-64 and NiTi via Laser Welding"

      Energies, volume 15, issue 19, p. 6949

    • 2021

      "Thermo-Mechanical Simulation of Ti6Al4V-NiTi Dissimilar Laser Welding Process"

      , volume 85062, p. V001T02A001

    • 2020

      "Thermal Stress Simulation Model of Dissimilar Linear Friction Welding (LFW) Technology for Manufacturing of Bi-Metallic Biomedical Implants"

      , volume 84256, p. V001T02A004

Headshot

Dr. Jae Joong Ryu joined Youngstown State University as an Assistant Professor of Mechanical Engineering in Fall 2014. Dr. JJ’s background and research activities include in the areas of small-scale mechanics of microdevices, biomaterials, tribomechanical engineering and manufacturing. He received his B.S., M.S., and Ph.D. in Mechanical Engineering from Iowa State University in 2003, 2005, and 2009, respectively. His doctoral work focused on addressing a biomechanical damage mechanism of metallic implants. 
Before joined in Youngstown State University, he served as an Assistant Professor in the Mechanical of Engineering at the University of Texas at Tyler and Texas A&M University at Kingsville.

  • Research Focus
    • Experimental mechanics of microdevices
    • Stress-assisted damage of biomedical implants
    • Mechanical response of textured surfaces
    • Mechanics of dissimilar joining processes
  • Expertise
    • Small-scale mechanics of microdevices
    • Experimental determination of surface stress developed by thermomechanical processes
    • Mechanical damage mechanism accelerated by biochemical environment
    • Dissimilar metal joining utilizing fiber laser welding and linear friction welding