Niobium phosphide is classified as aWeyl semimetal[2][3], characterized by linearly dispersing electronic bands near theFermi level that intersect at discrete points known as Weyl nodes. These nodes arise as a direct consequence of the material’s non-centrosymmetric crystal structure and strongspin–orbit coupling[4]. Experimental studies using angle-resolved photoemission spectroscopy (ARPES) have confirmed the existence of topologically protected surface states, known asFermi arcs, which connect the projections of Weyl nodes with oppositechirality[5]. The electronic structure gives rise to unusual transport behavior, including extremely largemagnetoresistance and highcarrier mobility, reflecting the small, compensated electron and hole pockets near the Weyl points and the topological nature of the band structure[6].
Niobium phosphide forms dark gray crystals of thenon-centrosymmetric,tetragonal system,space groupI4₁md (No. 109), with cell parametersa = 0.3334 nm,c = 1.1378 nm,Z = 4.[7][8], the same structure type as other transition-metal monopnictide Weyl semimetals such as TaAs and NbAs. The unit cell contains four formula units, and each niobium atom is coordinated by six phosphorus atoms and vice versa, forming a three-dimensional network of distorted polyhedra[4].
(100) orientation of NbP (left). Polyhedra coordination in NbP (right).
The compound is asemiconductor used in high power, high frequency applications and in laser diodes.[1]
Niobium phosphate is also being explored specifically for replacing copper as an ultra-thin nanometer film, where it exhibits much lower resistance than the conventional metal.[9]
NbP may be suitable for use in new electronic components.[10]
