Matter with apparent and hidden spin physics
Abstract
Materials with interesting physical properties are often designed based
on our understanding of the target physical effects. The physical
properties can be either explicitly observed (“apparent”) or concealed
by the perceived symmetry (“hidden”) but still exist. Both are enabled
by specific symmetries and induced by certain physical interactions.
Using the underlying approach of condensed matter theory of real
materials (rather than schematic model Hamiltonians), we discuss
apparent and hidden physics in real materials focusing on the properties
of spin splitting and spin polarization. Depending on the enabling
symmetries and underlying physical interactions, we classify spin
effects into four categories with each having two subtypes; representative
materials are pointed out. We then discuss the electric tunability and
switch of apparent and hidden spin splitting and polarization in
antiferromagnets. Finally, we extend “hidden effects” to views that are
farsighted in the sense of resolving the correct atomistic and
reciprocal symmetry and replaced by the incorrect higher symmetry.
This framework could guide and enable systematic discovery of such
intriguing effects.
Type
Publication
Matter 9, 4 (2026)

Authors
I develop predictive theories of condensed matter materials and propose them for experimentalists to make. My work pairs first-principles calculations with symmetry analysis to discover new classes of materials with interesting electronic and magnetic properties. Specific material class of interests include semicondcutors and ferroic materials. My recent interest extends to integrating these methods into agentic workflows to accelerate materials discovery.
I moved to Evanston in May 2023 to join the Rondinelli Group at Northwestern University as a research associate.