Actinide materials are the backbone of nuclear energy. In order to realize the full potential of nuclear power, and to avoid the risks for society and environment, there is a need in solid understanding of the physical and chemical properties of actinide materials. Theoretical modeling of the actinides and their 5f states is a challenging problem due to the interplay between the localized and the itinerant nature of the 5f-electrons.
PuCoGa5 has the highest critical temperature of 18.5 K among heavy-fermion superconductors, that is one order of magnitude higher than for typical heavy-fermion compounds. Spin and charge 5f-electron valence fluctuations may have an important role in mediation of the superconducting phase in the Pu-115 family of superconductors. Specific character of the coupling mechanism remains uncovered. Very recent point-contact spectroscopy experiments [2] show that the paired superconducting electrons have wavefunction with the d-wave symmetry.
We show that the unconventional character of superconductivity in the Pu-115 compounds and the unexpected absence of magnetism in δ-Pu may have a common origin in the intermediate-valence nature of the Pu 5f-electron ground state [3]. In all three compounds the Pu atoms exhibit a 5f5-5f6 intermediate-valence ground state, with a partial delocalization of the 5f5 multiplet. The local 5f magnetic moment is compensated by a magnetic moment in the surrounding cloud of conduction electrons. In the case of PuCoGa5 and δ-Pu the compensation is complete and the grounds state is a non-magnetic singlet. On the basis of these results, we discuss the role of spin and charge fluctuations for Cooper pairing, and the nature of the unconventional d-wave superconducting state in PuCoGa5 and PuCoIn5.
References
[1] J. L. Sarrao, L. A. Morales, J. D. Thompson, B. L. Scott, G. R. Stewart, F. Wastin, J. Rebizant, P. Boulet, E. Colineau, and G. H. Lander, Nature 420, 297 (2002).
[2] D. Daghero, M. Tortello, G. Ummarino, J.-C. Griveau, E. Colineau, R. Eloirdi, A. B. Shick, J. Kolorenc, A. I. Lichtenstein, and R. Caciuffo, Nature Comm. 3, 1785 (2012).
[3] A. B. Shick, J. Kolorenc, J. Rusz, P. M. Oppeneer, A. I. Lichtenstein, M. I. Katsnelson, and R. Caciuffo, Phys. Rev. B 87, 020505 (2013).