Weyl semimetals are a fascinating class of materials that exhibit unique electronic properties due to their topological characteristics. They are a type of topological semimetal, a category of materials that possess electronic band structures with nontrivial topological properties, leading to robust surface states and intriguing bulk electronic behavior. Weyl semimetals were theoretically predicted and later experimentally discovered, sparking significant interest in the field of condensed matter physics.
At the heart of Weyl semimetals are Weyl points, which are topological defects in the electronic band structure of the material. These points are named after the mathematician Hermann Weyl. In three-dimensional momentum space (k-space), Weyl points appear as isolated crossing points of two energy bands. Unlike traditional semimetals where conduction and valence bands touch along a line (known as a Dirac point), in Weyl semimetals, the bands touch at discrete points with a linear dispersion relation near the crossing point.
Key features and properties of Weyl semimetals include:
Chiral Fermions: The energy bands near a Weyl point are characterized by chiral fermions, which are massless particles that exhibit a chirality (handedness). The chirality determines the direction of particle's spin relative to its momentum. Importantly, these chiral fermions are protected by topology and are robust against certain types of perturbations that could otherwise scatter normal fermions.
Weyl Nodes: Weyl points always appear in pairs of opposite chirality. These pairs are known as Weyl nodes. When an external electric field is applied, the Weyl nodes can move in opposite directions along the field direction, giving rise to novel transport properties like the chiral magnetic effect.
Fermi Arcs: When a Weyl semimetal is cleaved to expose its surface, the Weyl nodes lead to the emergence of surface states known as Fermi arcs. These are open curves connecting the projections of the Weyl nodes onto the surface Brillouin zone. Fermi arcs are topologically protected states and are robust against disorder and impurities.
Anomaly-Induced Responses: Weyl semimetals display unique electromagnetic responses, such as the chiral anomaly. This anomaly describes the non-conservation of chiral charge in the presence of electric and magnetic fields, leading to novel transport phenomena.
Applications and Research: Weyl semimetals hold promise for various applications, particularly in electronics and optoelectronics. They have the potential to contribute to the development of novel devices such as highly efficient electronic components and advanced sensors. Researchers are also exploring their potential for realizing new states of matter and understanding fundamental principles of physics.
Overall, Weyl semimetals are an intriguing class of materials that exhibit a rich variety of electronic and topological properties. Their discovery has opened up new avenues for studying the interplay of topology, symmetry, and electronic behavior in condensed matter systems.