TY - JOUR
T1 - Spin-momentum locking from topological quantum chemistry
T2 - Applications to multifold fermions
AU - Lin, Mao
AU - Robredo, Iñigo
AU - Schröter, Niels B.M.
AU - Felser, Claudia
AU - Vergniory, Maia G.
AU - Bradlyn, Barry
N1 - Publisher Copyright:
© 2022 American Physical Society.
PY - 2022/12/15
Y1 - 2022/12/15
N2 - In spin-orbit coupled crystals, symmetries can protect multifold degeneracies with large Chern numbers and Brillouin zone spanning topological surface states. In this work, we explore the extent to which the nontrivial topology of chiral multifold fermions impacts the spin texture of bulk states. To do so, we formulate a definition of spin-momentum locking in terms of reduced density matrices. Using tools from the theory of topological quantum chemistry, we show how the reduced density matrix can be determined from the knowledge of the basis orbitals and band representation forming the multifold fermion. We show how onsite spin-orbit coupling, crystal-field splitting, and Wyckoff position multiplicity compete to determine the spin texture of states near chiral fermions. We compute the spin texture of multifold fermions in several representative examples from space groups P432 (207) and P213 (198). We show that the winding number of the spin around the Fermi surface can take many different integer values, from zero all the way to ±7. Finally, we conclude by showing how to apply our theory to real materials using the example of PtGa in space group P213.
AB - In spin-orbit coupled crystals, symmetries can protect multifold degeneracies with large Chern numbers and Brillouin zone spanning topological surface states. In this work, we explore the extent to which the nontrivial topology of chiral multifold fermions impacts the spin texture of bulk states. To do so, we formulate a definition of spin-momentum locking in terms of reduced density matrices. Using tools from the theory of topological quantum chemistry, we show how the reduced density matrix can be determined from the knowledge of the basis orbitals and band representation forming the multifold fermion. We show how onsite spin-orbit coupling, crystal-field splitting, and Wyckoff position multiplicity compete to determine the spin texture of states near chiral fermions. We compute the spin texture of multifold fermions in several representative examples from space groups P432 (207) and P213 (198). We show that the winding number of the spin around the Fermi surface can take many different integer values, from zero all the way to ±7. Finally, we conclude by showing how to apply our theory to real materials using the example of PtGa in space group P213.
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U2 - 10.1103/PhysRevB.106.245101
DO - 10.1103/PhysRevB.106.245101
M3 - Article
AN - SCOPUS:85143652402
SN - 2469-9950
VL - 106
JO - Physical Review B
JF - Physical Review B
IS - 24
M1 - 245101
ER -