Events

INESC MN Seminar – J. Ping Liu

Civil Engineering Museum, Técnico – Alameda campus

June 28th, at 2.30 p.m., Civil Engineering Museum, Técnico – Alameda campus

Date: June 28th
Hour: 2.30 p.m.
Venue: Civil Engineering Museum, Técnico – Alameda campus
More information: Official Site

The upcoming INESC-MN Seminar will be presented by J. Ping Liu and will take place on June 28th, at 2.30 p.m., at the Civil Engineering Museum of Instituto Superior Técnico.

Abstract:

How “hard” (coercive) a ferromagnet can be has been a puzzle for a century. Seven decades ago, William Fuller Brown offered his famous theorem to correlate coercivity with the magnetocrystalline anisotropy fields in ferromagnetic materials.
However, the experimental coercivity values have been far below the calculated levels given by the theorem, which is called Brown’s coercivity paradox. Researchers have attempted to solve the paradox with sustained efforts; however, the paradox remains unsolved, and coercivity still cannot be predicted and calculated quantitatively by modeling. Progress has been made in the past 20 years in understanding coercivity mechanisms in nanoscale low-dimensional ferromagnets. In fact, ferromagnetism is a size-dependent physical phenomenon, as revealed by theoretical studies. However, nanoscale ferromagnetic samples with controllable size and shape have been available only in recent times. By adopting newly developed salt-matrix annealing, surfactant-assisted milling, and improved hydrothermal and chemical solution techniques, we used a bottom-up approach to produce nanostructured magnets and have successfully synthesized monodisperse ferromagnetic Fe–Pt, Fe–Co, and Sm–Co nanoparticles and Co nanowires with extraordinary properties, which are strongly size- and shape-dependent. A study on size-dependent Curie temperature of the L10 ferromagnetic nanoparticles with sizes down to 2 nm has experimentally proved a finite-size effect. A systematic study of nanowires with extremely high coercivity above their magnetocrystalline anisotropy fields has opened a door to the solution of Brown’s paradox.

Biography:

J. Ping Liu received the Ph.D. degree in physics from the University of Amsterdam, Amsterdam, The Netherlands. For the past four decades, he has worked in research and development of permanent magnets and related magnetic materials in China, Europe, and USA. He is currently a Distinguished University Professor at The University of Texas at Arlington, Arlington, TX, USA. His current research has been focused on hard magnetic nanoparticles, thin films, and bulk nanocomposites, as reported in his more than 330 peer-reviewed journal articles, review articles, and books, including Nanoscale Magnetic Materials and Applications (Springer, 2009), Skyrmions: Topological Structures, Properties, and Applications (CRC Press, 2016), and Permanent Magnets: The History and Future (Science Press, 2020). He has supervised more than 50 graduate students and post-doctoral researchers. He received the Outstanding Achievement Award at the 25th International Workshop on Rare-Earth and Future Permanent Magnets and Their Applications in 2018. Dr. Liu is an elected fellow of the American Physical Society and IEEE.