The interplay of structural, orbital, charge, and spin degrees of freedom is at the heart of many emergent phenomena, including superconductivity. Unraveling the underlying forces of such novel phases is a great challenge because it not only requires understanding each of these degrees of freedom, it also involves accounting for the interplay between them. Cerium-based heavy fermion compounds are an ideal playground for investigating these interdependencies, and we present evidence for a correlation between orbital anisotropy and the ground states in a representative family of materials. We have measured the 4f crystal-electric field ground-state wave functions of the strongly correlated materials CeRh 1−x Ir x In 5 with great accuracy using linear polarization-dependent soft X-ray absorption spectroscopy. These measurements show that these wave functions correlate with the ground-state properties of the substitution series, which covers long-range antiferromagnetic order, unconventional superconductivity, and coexistence of these two states.heavy fermions | crystal fields | X-ray absorption | rare earth W hy do many chemically and structurally highly similar compounds develop different ground states? This seemingly simple question still eludes a straightforward description despite intense research. However, it is specifically pressing in view of the quest for a deeper insight into unconventional superconductivity.We here investigate heavy fermion metals, i.e., rare earth or actinide materials, in which a plethora of phenomena including antiferromagnetism and unconventional superconductivity can be observed. In these compounds, the f electrons hybridize with the conduction electrons (cf -hybridization), and, in analogy to the Kondo effect in diluted systems, the local magnetic moments can be screened in these so-called "Kondo lattices" at sufficiently low temperatures. However, the Kondo effect competes with the Ruderman-Kittel-Kasuya-Yosida interaction, which typically favors long-range magnetic order. As a result of this competition, a quantum phase transition from magnetically ordered to paramagnetic, more itinerant f electron behavior can take place. The balance of both interactions can be tuned by external parameters such as pressure, magnetic field, or doping (1). Non-Fermi liquid behavior and, of interest here, unconventional superconductivity often occur in the vicinity of such quantum critical points. However, despite research over the last 30 y, the ability to predict conditions favorable for superconductivity has remained elusive. Here, the cerium-115 family CeMIn 5 with M = Co, Ir, and Rh is ideally suited for a systematic study because ground states and changes in Fermi volumes in this family can be tuned easily by substitutions of one M element for another (2-25).These heavy fermion compounds CeMIn 5 crystallize in the tetragonal HoCoGa 5 -type structure as depicted in Fig. 1, with In1 being the in-plane and In2 the out-of-plane indium. Fig. 2 shows the substitution phase diagram of CeRhIn 5 , wher...
