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Sereni, J. G. First observation of Ce volume collapse in CeN., 2017.
Abstract: On the occasion of the 80th anniversary of the first observation of Ce volume collapse in CeN a remembrance of the implications of that transcendent event is presented, along with a review of the knowledge of Ce physical properties available at that time. Coincident anniversary corresponds to the first proposal for Ce as a mix valence element, motivating to briefly review how the valence instability of Ce was investigated since that time.
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Banda, J., D. Hafner, J. F. Landaeta, E. Hassinger, K. Mitsumoto, M. Giovannini, J. G. Sereni, C. Geibel, and M. Brando. Electronuclear Quantum Criticality., 2023.
Abstract: We present here a rare example of electronuclear quantum criticality in a metal. The compound YbCu4.6Au0.4 is located at an unconventional quantum critical point (QCP). In this material the relevant Kondo and RKKY exchange interactions are very weak, of the order of 1 K. Furthermore, there is strong competition between antiferromagnetic and ferromagnetic correlations, possibly due to geometrical frustration within the fcc Yb sublattice. This causes strong spin fluctuations which prevent the system to order magnetically. Because of the very low Kondo temperature the Yb3+ 4f-electrons couple weakly with the conduction electrons allowing the coupling to the nuclear moments of the 171Yb and 173Yb isotopes to become important. Thus, the quantum critical fluctuations observed at the QCP do not originate from purely electronic states but from entangled electronuclear states. This is evidenced by the anomalous temperature and field dependence of the specific heat at low temperatures.
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Zabala, J., P. Pedrazzini, F. J. Castro, and V. F. Correa. Enhanced weak superconductivity in trigonal γ-PtBi2. Vol. 2023., 2023.
Abstract: Electrical transport experiments show superconductivity in a high-quality single crystal of trigonal γ-PtBi2. The critical temperature shows a large dependence on the electrical current and in the limit of very low currents, a Tc = 1.1 K is observed, while a zero temperature critical field Bc(0) ≈ 1.5 Tesla is estimated. These are the highest superconducting parameters reported (at ambient pressure) in a stoichiometric γ-PtBi2 bulk sample so far. Under a magnetic field a strict zero resistance state is no longer observed even though an incipient superconducting transition is seen. Such a behavior is most probably associated with very low critical currents and is reminiscent of filamentary superconductivity. The superconducting state is elusive to magnetization measurements discarding a bulk phase down to T= 0.3 K.
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