Allan H. MacDonald explained

Allan H. MacDonald
Birth Date:1 December 1951
Birth Place:Antigonish, Nova Scotia, Canada
Nationality:Canadian, American
Fields:Condensed matter physics
Workplaces:University of Texas at Austin
Alma Mater:St. Francis Xavier University, University of Toronto

Allan H. MacDonald is a theoretical condensed matter physicist and the Sid W. Richardson Foundation Regents Chair Professor of Physics at The University of Texas at Austin.[1]

Education and early life

He was born in Antigonish, Nova Scotia, Canada, and attended local schools completing a B.S. at St. Francis Xavier University in 1973. He completed his Ph.D.in physics at The University of Toronto in 1978, working with S.H. Vosko on relativistic generalizations of density functional theory, and on the application of density functional theory to magnetism in metals.

Research and career

Prior to joining the University of Texas, he worked at the Ottawa laboratory of the National Research Council of Canada (1978–1987) and at Indiana University (1987–2000). He has held visiting positions at the Swiss Federal Institute of Technology in Zurich and the Max Planck Institute for Solid State Research in Stuttgart.

MacDonald's research has focused on new or unexplained phenomena related to the quantum physics of interacting electrons in materials. He has contributed to theories of the integer and fractional Quantum Hall effects, spintronics in metals and semiconductors, topological Bloch bands and momentum-space Berry curvature phenomena, correlated electron-hole fluids and exciton and polariton condensates, and two-dimensional materials.

In 2011 MacDonald and Rafi Bistritzer, a former postdoctoral researcher in MacDonald's lab, predicted that it would be possible to realize strong correlation physics in graphene bilayers twisted to a magic relative orientation angle, foreshadowing the field of twistronics. Pablo Jarillo-Herrero, an experimentalist at MIT, found that the magic angle resulted in the unusual electrical properties the UT Austin scientists had predicted. At 1.1 degrees rotation at sufficiently low temperatures, electrons move from one layer to the other, creating a lattice and the phenomenon of superconductivity. The magic angle allows electric current to pass unimpeded, apparently without energy loss. This could lead to more efficient electrical power transmission or new materials for quantum applications.

His recent work is focused on anticipating new physics in moire superlattices, and on achieving a full understanding of magic-angle bilayer graphene and transition-metal dichalcogenide moire superlattice systems.

Honors and awards

MacDonald received the Canadian Association of Physicists's Herzberg Medal in 1987, the Oliver E. Buckley Prize of the American Physical Society in 2007, the Ernst Mach Honorary Medal of the Czech Academy of Sciences in 2012, and the Wolf Prize in Physics in 2020.  He was elected to the American Academy of Arts and Sciences in 2005 and the National Academy of the Sciences in 2012.

Notes and References

  1. Web site: MACDONALD, ALLAN H - Physics - CNS Directory . 2023-07-02 . ph.utexas.edu.