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John Perepezko

John Perepezko

IBM Bascom Professor
gscholar website
lab website

As a result of our efforts in the analysis and modeling of alloy solidification it has been possible to identify new microstructural morphologies and to establish processing conditions where nucleation controlled kinetics dominates the microstructural evolution. This basic information can be applied to understand grain refinement and novel microstructures in cast and rapidly solidified alloys. It also is used to guide microgravity materials processing and alloy design including the solidification processing of composite materials. Extreme solidification conditions at high rates and /or high undercooling often result in metastable phases and amorphous alloys. Our work on amorphous Al alloys has focused on understanding glass formation and the primary crystallization reaction that yields a high density of Al nanocrystals. Interestingly, similar microstructures can be synthesized by the repeated cold rolling of elemental multilayers as a driven system processing where the deformation induced alloying at interfaces is a key issue for study.

Our work has yielded new understanding on the nucleation of phases during interdiffusion and interface reaction in thin-film multilayers. With this understanding we have developed the concept of a kinetic bias and have demonstrated the application of biasing to control diffusion pathways and produce phase selection during interfacial reactions in multicomponent systems. These concepts provide for an effective strategy to synthesize structural composites by in-situ reactions and also to develop electronic materials such as photovoltaics or high-temperature devices from multilayers. We have recently extended the capability of using in-situ reactions and kinetic biasing to the design of robust coatings that exhibit self-healing behavior as well as oxidation protection at high temperature.

Other studies of multiphase microstructures involve examining high-temperature alloys such as superalloys, titanium aluminide intermetallics and refractory alloys. The examination of phase stability and reaction kinetics during processing provides a basis for the achievement of tailored microstructures and alloy designs to enhance performance in structural applications as demonstrated in advanced Mo-Si-B alloys.

Department

Materials Science & Engineering

Contact

1121, Engineering Research Building
1500 Engineering Dr
Madison, WI
p: (608) 263-1678

  • PhD 1973, Carnegie-Mellon University
  • MS 1968, Polytechnic Institute of New York
  • BS 1967, Polytechnic Institute of New York

  • Phase transformations
  • Interface reactions / coating design
  • Metastable and amorphous phases
  • Kinetics
  • Nucleation
  • Metal powders and high temperature intermetallic alloys
  • Rapid solidification
  • Microgravity processing

  • 2024 Univ. of Wisconsin-Madison, Hilldale Award-Physical Sciences
  • 2022 American Association for the Advancement of Science, Elected Fellow
  • 2021 Intermetallics International Conference, Senior Scientist award
  • 2020 ASM International , Albert Easton White Distinguished Teacher Award
  • 2019 ASM Cleveland Chapter, Zay Jeffries Award Lecture
  • 2017 ASM International , Gold Medal
  • 2014 Helmholtz Gemeinschaft, International Fellow Award
  • 2013 Materials Research Society, Elected Fellow
  • 2008 TMS, William Hume-Rothery Award
  • 2005 Japan Society for the Promotion of Science, Visiting Researcher Award
  • 2004 Forschungszentrum Karlsruhe, Research Visit Fellowship
  • 2004 TMS, Elected Fellow
  • 2004 National Academy of Engineering, Elected to the National Academy of Engineering
  • 2004 ISMANAM Conference, Senior Research Award
  • 1997 TMS, Bruce Chalmers Award
  • 1997 College of Engineering, Univ. of Wisconsin-Madison, Byron Bird Award for Outstanding Research
  • 1996 Alexander von Humboldt Stiftung (Germany), Senior Research Prize Award
  • 1995 NATO, AGARD (NATO) Visiting Lectureship to ONERA
  • 1994 MRS, Best Poster Award
  • 1994 Allied-Signal, Research Award
  • 1989 Crystal Growth Society - Pittsburgh Chapter , Outstanding Research Award
  • 1989 College of Engineering, Univ. of Wisconsin-Madison, Polygon Outstanding Professor Award
  • 1988 American Society for Metals-Milwaukee Chapter, Outstanding Service Award
  • 1987 American Society for Metals, Elected Fellow
  • 1985 College of Engineering, Univ. of Wisconsin-Madison, Polygon Outstanding Professor Award
  • 1983 College of Engineering, Univ. of Wisconsin-Madison, Polygon Outstanding Professor Award
  • 1982 National Science Foundation, Exceptional Creativity Award
  • 1980 Alcoa Foundation, Research Award
  • 1978 American Society for Metals , Bradley S. Stoughton Award for Outstanding Young Teacher
  • 1978 Who's Who in Engineering
  • 1976 Deutscher Akademischer Austauschdienst, Study-Visit Fellowship
  • Univ. of Wisconsin-Madison, IBM Bascom Professorship

  • Duan, T., Kim, W., Gao, M., & Perepezko, J. (2024). Crystallization of an undercooled Zn-based glass forming alloy. Journal of Non-Crystalline Solids, 627, 122823.
  • Wei, S., Qureshi, M. W., Xi, J., Kim, J. Y., Wang, X., Wei, J., Su, R., Liu, L., Nachlas, W. O., Perepezko, J., & others, (2024). Radiation induced segregation in titanium diboride. Acta Materialia, 267, 119739.
  • Wang, Z., & Perepezko, J. (2024). Surface diffusion on a palladium-based metallic glass. Applied Physics Letters, 124(9).
  • Wu, X., Abdallah, I., Jiang, W., Ullberg, R. S., Phillpot, S. R., Couet, A., Perepezko, J., & Tonks, M. R. (2023). A phase-field study of stainless-steel oxidation from high-temperature carbon dioxide exposure. Computational Materials Science, 218, 111996.
  • Su, R., Liu, L., & Perepezko, J. (2023). Alloy designs for high temperature Mo-base systems. International Journal of Refractory Metals and Hard Materials, 113, 106199.
  • Hu, X., Liu, N., Jambur, V., Attarian, S., Su, R., Zhang, H., Xi, J., Luo, H., Perepezko, J., & Szlufarska, I. (2023). Amorphous shear bands in crystalline materials as drivers of plasticity. Nature Materials, 22(9), 1071--1077.
  • Su, R., Zhang, H., Liu, L., & Perepezko, J. (2023). Boron capture stabilizing the diffusion barriers in a two-step Mo-Si-B coated refractory multi-principal element alloy. Corrosion Science, 221, 111365.
  • Ouyang, G., Singh, P., Su, R., Johnson, D. D., Kramer, M. J., Perepezko, J., Senkov, O. N., Miracle, D., & Cui, J. (2023). Design of refractory multi-principal-element alloys for high-temperature applications. npj Computational Materials, 9(1), 141.
  • Su, R., Shi, L., Perepezko, J., & Zhang, H. (2023). Helium-driven element depletion and phase transformation in irradiated Ti3SiC2 at high temperature. Journal of the European Ceramic Society, 43(8), 3104--3111.
  • Thoma, D. J., Spethson, J. T., Francis, C. S., Voyles, P. M., & Perepezko, J. (2023). High-Throughput Synthesis and Characterization Screening of Mg-Cu-Y Metallic Glass. Metals, 13(7), 1317.

  • M S & E 465 - Fundamentals of Heat Treatment (Spring 2025)
  • M S & E 990 - Research and Thesis (Spring 2025)
  • M S & E 463 - Materials for Elevated Temperature Service (Fall 2024)
  • M S & E 990 - Research and Thesis (Fall 2024)
  • M S & E 990 - Research and Thesis (Summer 2024)
  • M S & E 352 - Materials Science-Transformation of Solids (Spring 2024)
  • M S & E 990 - Research and Thesis (Spring 2024)
  • M S & E 465 - Fundamentals of Heat Treatment (Fall 2023)
  • M S & E 699 - Independent Study (Fall 2023)
  • M S & E 990 - Research and Thesis (Fall 2023)
  • M S & E 990 - Research and Thesis (Summer 2023)