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Luca Mastropasqua

Luca Mastropasqua

Assistant Professor
gscholar website
lab website

Dr. Luca Mastropasqua is an Assistant Professor at the University of Wisconsin-Madison’s Department of Mechanical Engineering. He is the principal investigator of the Hydrogen and Electrochemical Research for Decarbonization (HERD) Lab. Dr. Mastropasqua’s research focuses on the conceptualization of new electrochemical devices and their integration into energy conversion and industrial processes. His chief research goal is to use electrochemical technologies to provide power generation, grid energy storage, and decarbonize sectors such as aviation, freight, shipping, steel, and cement production via electrochemical synthesis of high-value products. Prior to joining UW-Madison, Dr. Mastropasqua was a Senior Scientist at the University of California, Irvine’s National Fuel Cell Research Center (NFCRC), and a Postdoctoral Associate at Princeton University. Dr. Mastropasqua received his PhD cum laudae from Politecnico di Milano in 2017 in Energy and Nuclear Science and Technology, one M.Sc. in Energy Engineering from Politecnico di Milano, and one in Thermal Engineering from Cranfield University.

Department

Mechanical Engineering

Contact

127, Engineering Research Building
1500 Engineering Dr
Madison, WI

Professor Luca Mastropasqua, Mechanical Engineering, University of Wisconsin-Madison

  • PhD 2017, Politecnico di Milano - School of Industrial Engineering – Department of Energy
  • MS 2014, Politecnico di Milano - School of Industrial Engineering – Department of Energy
  • MS 2014, Cranfield University - School of Engineering
  • BS 2011, Politecnico di Milano - School of Industrial Engineering – Department of Energy

  • Electrochemical Devices
  • Electrochemical Systems
  • Renewable Energy Sources
  • Energy Conversion Systems
  • Energy Storage
  • Chemical Plant Design
  • Energy Scenarios and Climate Change
  • Turbomachinery

  • 2024 University of Wiscsonsin-Madison, Vilas Early-Career Investigator Award
  • 2024 APRA, ARPA-E IGNIITE Award
  • 2023 University of Wisconsin-Madison, Ragland Family Faculty Fellowship
  • 2019 ASME 2019, ASME Certificate of Appreciation
  • 2018 ASME 2018, ASME Best Paper Award
  • 2018 ASME 2018, ASME Certificate of Appreciation
  • 2017 ASME 2017, ASME Best Paper Award
  • 2014 Edison S.p.a, Edison S.p.a Research Development & Innovation scholarship
  • 2014 Cranfield University – MSc Thermal Power, R-MC Power Recovery Ltd Prize
  • 2012 Cranfield University, MSc Departmental Grant
  • 2012 Erasmus, Erasmus Scholarship

  • Scaccabarozzi, R., Artini, C., Mastropasqua, L., Mapelli, C., Brouwer, J., Kim, J., Ghezel-Ayagh, H., Lehman, P., Jampani, M., Cavlovich, N., & others, (2025). Technical analysis of high-efficiency and flexible direct reduced iron plants integrated with high-temperature electrolysis. Journal of Cleaner Production, 144681.
  • Lu, Y. E., Rezaei, S., Hintz, E., Balooch, M., Hosemann, P., Brouwer, J., & Mastropasqua, L. (2024). Thermo-Mechanical Properties and Benefits of Borosilicate Glass for SOEC Sealants. In Electrochemical Society Meeting Abstracts 245 (pp. 2286–2286).
  • Di Micco, S., Cigolotti, V., Mastropasqua, L., Brouwer, J., & Minutillo, M. (2024). Ammonia-powered ships: Concept design and feasibility assessment of powertrain systems for a sustainable approach in maritime industry. Energy Conversion and Management: X, 22, 100539.
  • Kim, J. Y., Mastropasqua, L., Saeedmanesh, A., & Brouwer, J. (2024). Investigating electric heater failure scenarios in solid oxide electrolysis cell systems with a novel three-dimensional dynamic SOEC stack model. Energy Conversion and Management: X, 24, 100805.
  • Kim, J. Y., Mastropasqua, L., Saeedmanesh, A., & Brouwer, J. (2024). Sustained long-term efficiency in solid oxide electrolysis systems through innovative reversible electrochemical heat management. Energy Conversion and Management, 308, 118405.
  • Rose, C., Mastropasqua, L., & Brouwer, J. (2023). Accelerated Stress Testing of Solid Oxide Electrolysis Cells in a Symmetric Steam-Rich Atmosphere. ECS Transactions, 111(6), 1231.
  • Crespi, E., Guandalini, G., Mastropasqua, L., Campanari, S., & Brouwer, J. (2023). Experimental and theoretical evaluation of a 60 kW PEM electrolysis system for flexible dynamic operation. Energy conversion and management, 277, 116622.
  • Rose, C., Mastropasqua, L., & Brouwer, J. (2023). Ni-and Ni-Sn Anode Porous Layers for SOFCs Operating with Carbonaceous Fuels. ECS Transactions, 111(6), 61.
  • Hardy, J. S., Bao, J., Kozlov, A., Mastropasqua, L., Cammarata, A., Mastropasqua, L., Cammarata12, A., & Mastropasqua, L. (2023). OPEN ACCESS EDITED BY. Rising Stars in Energy Research: 2022, 106.
  • Cammarata, A., & Mastropasqua, L. (2023). Theoretical analysis of mixed open-circuit potential for high temperature electrochemical cells electrodes. Frontiers in Energy Research, 11, 1120343.

  • M E 370 - Energy Systems Laboratory (Spring 2025)
  • M E 489 - Honors in Research (Spring 2025)
  • M E 790 - Master's Research and Thesis (Spring 2025)
  • M E 890 - PhD Research and Thesis (Spring 2025)
  • CHEM 699 - Directed Study (Fall 2024)
  • M E 491 - Mechanical Engineering Projects I (Fall 2024)
  • M E 601 - Special Topics in Mechanical Engineering (Fall 2024)
  • M E 790 - Master's Research and Thesis (Fall 2024)
  • M E 890 - PhD Research and Thesis (Fall 2024)
  • M E 491 - Mechanical Engineering Projects I (Summer 2024)
  • M E 790 - Master's Research and Thesis (Summer 2024)
  • M E 890 - PhD Research and Thesis (Summer 2024)
  • M E 352 - Interdisciplinary Experiential Design Projects II (Spring 2024)
  • M E 790 - Master's Research and Thesis (Spring 2024)
  • M E 890 - PhD Research and Thesis (Spring 2024)
  • CHEM 699 - Directed Study (Fall 2023)
  • M E 351 - Interdisciplinary Experiential Design Projects I (Fall 2023)
  • M E 370 - Energy Systems Laboratory (Fall 2023)
  • M E 790 - Master's Research and Thesis (Fall 2023)
  • M E 890 - PhD Research and Thesis (Fall 2023)