Fermi surface in the hidden-order state of URu2Si2 under intense pulsed magnetic fields up to 81~T

Abstract

We present measurements of the resistivity x,x of URu2Si2 high-quality single crystals in pulsed high magnetic fields up to 81~T at a temperature of 1.4~K and up to 60~T at temperatures down to 100~mK. For a field H applied along the magnetic easy-axis c, a strong sample-dependence of the low-temperature resistivity in the hidden-order phase is attributed to a high carrier mobility. The interplay between the magnetic and orbital properties is emphasized by the angle-dependence of the phase diagram, where magnetic transition fields and crossover fields related to the Fermi surface properties follow a 1/θ-law, θ being the angle between H and c. For Hc, a crossover defined at a kink of x,x, as initially reported in [Shishido et al., Phys. Rev. Lett. 102, 156403 (2009)], is found to be strongly sample-dependent: its characteristic field μ0H* varies from 20~T in our best sample with a residual resistivity ratio RRR of 225 to 25~T in a sample with a RRR of 90. A second crossover is defined at the maximum of x,x at the sample-independent characteristic field μ0H,maxLT30~T. Fourier analyzes of SdH oscillations show that H,maxLT coincides with a sudden modification of the Fermi surface, while H* lies in a regime where the Fermi surface is smoothly modified. For Ha, i) no phase transition is observed at low temperature and the system remains in the hidden-order phase up to 81~T, ii) quantum oscillations surviving up to 7~K are related to a new and almost-spherical orbit - for the first time observed here - at the frequency Fλ1400~T and associated with a low effective mass m*λ=(10.5)· m0, and iii) no Fermi surface modification occurs up to 81~T.