Campbell penetration depth in a single crystal of heavy fermion superconductor CeCoIn5

Abstract

The temperature and magnetic field dependent magnetic penetration depth, λm(T,H), was measured in a single crystal of a heavy fermion superconductor CeCoIn5 using a frequency-domain tunnel diode resonator. In addition to the London penetration depth, which yields the superfluid density, measurements in a finite DC magnetic field provide Campbell penetration depth, λC(T,H), which is directly linked to the true (unrelaxed) critical current density, Jc. The measured λC(H) in CeCoIn5 deviates significantly from the conventional H behavior, and its slope changes abruptly at the characteristic magnetic field values. Considering that our sample is in the clean limit, we interpret this deviation as a fingerprint of the vortex lattice symmetry change. The temperature dependence Jc(T) of CeCoIn5 calculated from λC(T) is nearly T-linear over the entire temperature range, also in stark contrast to expectations in a conventional type-II superconductor. Our results provide new evidence for unconventional superconductivity in CeCoIn5 from the never-before-measured Campbell penetration depth.