Different shapes of spin textures as a journey through the Brillouin zone
Abstract
Crystallographic space group symmetry (CPGS) such as polar and nonpolar
crystal classes have long been known to classify compounds that have
spin-orbit-induced spin splitting. While taking a journey through the
Brillouin Zone (BZ) from one k-point to another for a fixed CPGS, it is
expected that the wavevector point group symmetry (WPGS) can change, and
consequently a qualitative change in the texture of the spin polarization
(the expectation value of spin operator $\vec{S}^{nk_{0}}$ in Bloch state
$u(n,k)$ and the wavevector $k_0$). However, the nature of the spin texture
(ST) change is generally unsuspected. In this work, we determine a full
classification of the linear-in-$k$ spin texture patterns based on the
polarity and chirality reflected in the WPGS at $k_0$. The spin-polarization
vector $\vec{S}^{nk_{0}}$ controlling the ST is bound to be parallel to the
rotation axis and perpendicular to the mirror planes and hence, symmetry
operation types in WPGSs impose symmetry restriction to the ST. For
instance, the ST is always parallel to the wavevector $k$ in non-polar
chiral WPGSs since they contain only rotational symmetries. Some
consequences of the ST classification based on the symmetry operations in
the WPGS include the observation of ST patterns that are unexpected
according to the symmetry of the crystal. For example, it is usually
established that spin-momentum locking effect requires the crystal
inversion symmetry breaking by an asymmetric electric potential. However,
we find that polar WPGS can have this effect even in compounds without
electric dipoles or external electric fields. We use the determined
relation between WPGS and ST as a design principle to select compounds
with multiple ST near band edges at different $k$-valleys. Based on
high-throughput calculations for 1481 compounds, we find 37 previously
fabricated materials with different ST near band edges.
Type
Publication
Physical Review B 104, 104408 (2021)

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.