Prof. Heremans was educated at the École Polytechnique de Louvain, the college of engineering of the Catholic University of Louvain where he received Bachelor of Science degree in Electrical Engineering in 1975 followed by a Doctor of Applied Sciences degree in Applied Physics in 1978. His Ph.D. training included a Research Fellowship with the Belgian Institute for Research in Industry and Agriculture. Following his formal education, Prof. Heremans worked as invited postdoctoral scientist, including at the Oersted Institute at the University of Copenhagen, where he worked under the direction of Prof. Ole P. Hansen, the Massachusetts Institute of Technology, where he worked under the direction of Prof. Millie Dresselhaus, and the Institute for Solid State Physics at the University of Tokyo, where he worked under the direction of Prof. Seichi Tanuma. Concurrently with these postdoctoral assignments, he worked as a researcher for the Fonds National Belge de la Recherche Scientifique.
Career and research
Prof. Heremans’ research involves experimental investigation of electron, magnon, and phonon transport properties; narrow-gap semiconductor physics, semimetals, and nanostructures. His early work at GM focused on PbTe-based infrared diode lasers and other properties of semiconductors. In the 1990s, Prof. Heremans developed the geometrical magnetoseebeck and magnetoresistance effects, the latter of which resulted in commercial position sensors used on crank and camshafts by GM. In the early 2000s, his work on quantum wires resulted in the discovery of large thermopowers due to size-quantization effects. In 2008, his team published evidence that resonant levels increase the thermoelectric figure of merit, zT, in PbTe by distorting the electronic density of states. The focus of his laboratory switched to spin caloritronic effects around 2010. In 2012, his team published data proving the giant spin-Seebeck effect in a non-magnetic material; they demonstrated that the giant spin-Seebeck effect in InSb is as large as the largest thermopower values ever measured. In 2015, his team published experimental proof that phonons in diamagnets respond to magnetic fields, proving that heat and sound can be controlled magnetically. In a recent review paper, he outlines the difficulties in obtaining truly electrically insulating topological insulators. Most recently, he and several colleagues developed goniopolar materials, materials that, due to the specific shape and topology of their Fermi surface, display simultaneous n- and p-type behavior of the same charge carriers, depending on the direction and type of measurement. In his career, he has published over 250 publications in refereed journals and conference proceedings. These publications have been cited over 11,000 times, with his most-cited paper "Enhancement of Thermoelectric Efficiency in PbTe by Distortion of the Electronic Density of States," which has been cited more tha 1800 times. He has been issued 39 U.S. patents and co-edited two books.
Honors and awards
In 1987, Prof. Heremans was named fellow of the American Physical Society for his pioneering work in the thermal conductivity of low-dimensional materials and electronic magnetostriction; and for the study of electronic and thermal properties of narrow-gap semiconductors , semimetals, and graphite intercalation compounds. In 2011, he was named fellow of American Association for the Advancement of Science, and he was elected to the National Academy of Engineering in 2013. Prof. Heremans has won several awards at OSU: the Clara M. and Peter L. Scott Award for Excellence in Engineering Education, the Lumley Interdisciplinary Research Award, the Lumley Award, the Innovators Award, and the Inventor of the Year Award. At GM he was the recipient of the John M. Campbell Award, the Charles L. McCuen Award, and the Charles F. Kettering Award. At Delphi he was elected to the Inventors Hall of Fame, Gold Level, and won the Scientific Excellence Award.
