We report the occurrence of reentrant metallic behavior in the Weyl semimetal
NbP. When the applied magnetic field H is above a critical value Hc, a
reentrance appears as a peak in the temperature dependent resistivity
ρxx(T) at T = Tp, similar to that observed in graphite where it
was attributed to local superconductivity. The Tp(H) relationship follows a
power-law dependence Tp∼(H−Hc)1/v where v can be derived from the
temperature dependence of the zero-field resistivity ρ0(T)∼Tv. From
concurrent measurements of the transverse ρxx(T) and Hall
ρxy(T) magnetoresistivities, we reveal a clear correlation between the
rapidly increasing ρxy(T) and the occurrence of a peak in the
ρxx(T) curve. Quantitative analysis indicates that the reentrant
metallic behavior arises from the competition of the magneto conductivity
σxx(T) with an additional component
Δσxx(T)=κHσxx(T) where
κH=[ρxy(T)/ρxx(T)]2 is the Hall factor. We find that the
Hall factor (κH≈0.4) at peak temperature Tp is nearly
field-independent, leading to the observed Tp(H) relationship. Furthermore,
the reentrant metallic behavior in ρxx(T) also is reflected in the
behavior of ρxx(H) that ranges from non-saturating at T>70 K to
saturation at liquid helium temperatures. The latter can be explained with the
magnetic field dependence of the Hall factor κH(H). Our studies
demonstrate that a semiclassical theory can account for the 'anomalies' in the
magnetotransport phenomena of NbP without invoking an exotic mechanism.Comment: To appear in Phys. Rev.