Prof. Alex Zunger of the University of Colorado, Boulder research field is Condensed Matter Theory of Real Materials, involving foundational work on Density Functional Theory, Pseudopotential theory, Quantum Nanostructures,Photovoltaicmaterials and Materials by Design. He is the recipient of the year 2018Boer Medalfor photovoltaic research, the 2013Hume- Rothery Awardon Theory of alloys, the 2011 (inaugural)“Materials Theory Award”of the Materials Research Society on Inverse Design, the 2010 “Tomassoni Prize“(Italy) and “2010 Medal of the Schola Physica Romana“ celebrating the tradition of E. Fermi, the2001John Bardeenaward of The Material Societyon “Spontaneous Ordering in semiconductor alloys”, the2001Rahman Awardof the American PhysicalSocietyon ‘foundational development of First Principles methods’, and the 2009GutenbergAward(Germany) on correlated electron systems. He is a Fellow of the American Physical Society; Fellow of the Materials Research Society, Sakler Fellow of the Institute of advanced studies of Tel Aviv University.He received his Ph.D. from Tel-Aviv University, Tel Aviv Israel where he worked with Prof. Joshua Jortner and Binyamin Englman on quantum theory of molecular solids. He did his postdoctoral research at the Physics Dept. of Northwestern University (with Art Freeman). He then received theIBM Fellowship, which he spent at the Physics Dept. of U.C. Berkeley (with Marvin Cohen). Dr. Zunger established the Solid-State Theory group at theNationalRenewable EnergyLaboratory (NREL) Golden, Colorado, a position he held 1978-2010 where he has been an“Institute Research Fellow”. He has been the founding Director of the $20 million ‘Center for Inverse Design’ (a DOE Energy Frontier Research Center). He moved to CU Boulder in 2010 where he continued as Chief Scientist of the NREL EFRC for 3 years. The impact of Dr. Zunger’s work is partially reflected by the high number of citations his papers have received (over 95,000, according to Google Scholar) and by his “h-number” of 140 (i.e., 140 of his papers were cited each at least 140 times). He is theauthorof the fifth-most-cited paper in the 110-year history of Physical Review (out of over 350,000 articles published in that journal) .In the course of his research; he has authored more than 600 articles in refereed journals, which includes over 150 articles in Physical Review Letters and Rapid Communications (PRB) and three citation classics. He has also trained more than 82 post-doctoral fellows. Declared by the Institute of Scientific Information (ISI) as the 39th most-cited physicist out of more than 500,000 physicists examined, based on publications in 1981–1997 in all branches of physics.Nominator and consultant for the Physics Nobel Committee in past 5 years.
Alex's Recent RASEI Activities
Impact of symmetry breaking and spin-orbit coupling on the band gap of halide perovskites
PHYSICAL REVIEW B, 2024, 110, 035160 Read more
Light-Induced Frenkel Defect Pair Formation Can Lead to Phase-Segregation of Otherwise Miscible Halide Perovskite Alloys
ADVANCED ENERGY MATERIALS, 2023, 2301539 Read more
Uncovering spin-orbit coupling-independent hidden spin polarization of energy bands in antiferromagnets
NATURE COMMUNICATIONS, 2023, 14, 5301 Read more
Insulating band gaps both below and above the Néel temperature in d-electron LaTiO3, LaVO3, SrMnO3, and LaMnO3 perovskites as a symmetry-breaking event
PHYSICAL REVIEW B, 2023, 074406 Read more
Degeneracy Removal of Spin Bands in Collinear Antiferromagnets with Non-Interconvertible Spin-Structure Motif Pair
ADVANCED MATERIALS, 2023, 35, 31, 2211966 Read more
Hidden Zeeman-type spin polarization in bulk crystals
PHYSICAL REVIEW B, 2023, 107, L081201 Read more
Rise and fall of Mott Insulating gaps in YNiO3 paramagnets as a reflection of symmetry breaking and remaking
PHYSICAL REVIEW MATERIALS, 2023, 7, 044409 Read more
Density functional description of spin, lattice, and spin-lattice dynamics in antiferromagnetic and paramagnetic phases at finite temperatures
Phys. Rev. B., 2022, 106, 134406 Read more
Bridging the gap between density functional theory and quantum materials
Nature Computational Science, 2022, 2, 529-532 Read more
Density functional thermodynamic description of spin, phonon and displacement degrees of freedom in antiferromagnetic-to-paramagnetic phase transition in YNiO3
Materials Today Physics, 2022, 27, 100805 Read more
Intrinsic local symmetry breaking in nominally cubic paraelectric BaTiO3
Phys. Rev. B., 2022, 105, 224108 Read more
Dependence of band gaps in d-electron perovskite oxides on magnetism
Phys. Rev. B., 2022, 105, 165111 Read more