Abstract
We present an extensive study of angle-dependent transverse magnetoresistance in bismuth, with a magnetic field perpendicular to the applied electric current and rotating in three distinct crystallographic planes. The observed angular oscillations are confronted with the expectations of semi-classic transport theory for a multi-valley system with anisotropic mobility and the agreement allows us to quantify the components of the mobility tensor for both electrons and holes. A quadratic temperature dependence is resolved. As Hartman argued long ago, this indicates that inelastic resistivity in bismuth is dominated by carrier-carrier scattering. At low temperature and high magnetic field, the threefold symmetry of the lattice is suddenly lost. Specifically, a $2\pi/3$ rotation of magnetic field around the trigonal axis modifies the amplitude of the magneto-resistance below a field-dependent temperature. By following the evolution of this anomaly as a function of temperature and magnetic field, we mapped the boundary in the (field, temperature) plane separating two electronic states. In the less-symmetric state, confined to low temperature and high magnetic field, the three Dirac valleys cease to be rotationally invariant. We discuss the possible origins of this spontaneous valley polarization, including a valley-nematic scenario.
Highlights
Electric conduction in solids is affected by the application of magnetic field in a variety of ways
The angleresolved Landau spectrum has been found to become exceptionally complex in high magnetic field
In the case of holes, on the other hand, as seen in Fig. 7, a difference is visible at low temperature: the mobilities extracted from the data saturate to values significantly lower than what is found in the zero-field limit
Summary
Electric conduction in solids is affected by the application of magnetic field in a variety of ways. According to two sets of experimental studies [11,14], the three Dirac valleys become inequivalent at low temperature and high magnetic field The origin of this spontaneous loss of threefold symmetry is yet to be understood. Metals hosting a small concentration of high-mobility carriers and displaying a large magnetoresistance have attracted much recent attention In dilute metals such as WTe2 [15] or Cd3As2 [16], resistivity is enhanced by many orders of magnitude upon the application of a magnetic field of 10 T. Except for a number of important details, our experimental results are in reasonable agreement with the expectations of the semiclassic theory This paves the way to a quantitative understanding of transverse magnetoresistance in bismuth with obvious implications for other semimetals and dilute metals. None of the currently available pictures provide an adequate description of the whole range of experimental facts
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