Leiden University Scholarly Publications

Electrons in a crystal lattice have properties that may differ from those of a free electron in vacuum. The effective mass can be different from the bare electron mass, and it may even vanish,
so that the electron behaves in some respects as a relativistic massless particle such as a photon. The magnetic moment of the intrinsic angular momentum, the electron spin,
may be also different from that of an elementary particle. Spin-like degrees of freedom, referred to as "pseudospin" or "valley isospin", can also arise in the effective low-energy description
of electrons in the lattice fields.
These various degrees of freedom are of interest as ways to store and transport information: one speaks of "spintronics" and "valleytronics" as alternatives to "electronics".
For these purposes it is of interest to study the interplay between the orbital motion of electrons and their spin (spin-like) degrees of freedom,
the...

Electrons in a crystal lattice have properties that may differ from those of a free electron in vacuum. The effective mass can be different from the bare electron mass, and it may even vanish,
so that the electron behaves in some respects as a relativistic massless particle such as a photon. The magnetic moment of the intrinsic angular momentum, the electron spin,
may be also different from that of an elementary particle. Spin-like degrees of freedom, referred to as "pseudospin" or "valley isospin", can also arise in the effective low-energy description
of electrons in the lattice fields.
These various degrees of freedom are of interest as ways to store and transport information: one speaks of "spintronics" and "valleytronics" as alternatives to "electronics".
For these purposes it is of interest to study the interplay between the orbital motion of electrons and their spin (spin-like) degrees of freedom,
the so-called "spin-orbit coupling".
In some systems where this interaction is strong, it causes the electron spin to be tied to the direction of motion.
This thesis contains results about the effects of this "spin-momentum locking" on two classes of materials, oxide interfaces
and Weyl semimetals, with a focus on their electrical transport properties.