Introduction

In intermetallics, Ce is close to the trivalent 4f1(5d6s)3 configuration with slight to moderate 4f0(5d6s)4 and 4f2(5d6s)2 admixtures. The 4f2 configuration with double f occupancy is rather unfavourable due to the strong onsite Coulomb repulsion compared to the 4f binding energy, and its contribution usually does not exceed a few percent. In contrast, the tetravalent 4f0 lies energetically closer to 4f1 which often leads to a fluctuating valence between both configurations. Therefore, the unusual phase diagrams in many Ce systems result from a competition between the non-magnetic 4f0 and the magnetic 4f1 ground state configuration with momentum J=5/2.

At the level of the Anderson impurity model with hybridization between 4f and valence band states, the competition is resolved through the Kondo quenching of the 4f1 magnetic moment and the resulting appearance of the Kondo resonance at the Fermi energy (EF) in the single-particle spectral function. The resonance reflects final states with a predominantly 4f1 contribution for both the electron removal and addition spectrum. In Kondo lattices, it can be understood as the momentum integrated coherent quasi-particle part of the single particle spectrum1. In a crystalline environment, the degeneracy of the Ce 4f15/2 sextet is lifted due to the interaction with the nonspherical electrostatic field of the ligands, which is called the crystal electric field (CEF). The resulting CEF splitting strongly influences the magnetic properties of the compound2. The Kondo lattice quasi-particles form heavy bands originating from the CEF split 4f1 states. If the magnetic moments are Kondo quenched, then these bands disperse across EF so that the 4f electrons enter the Fermi volume, resulting in the so-called large Fermi surface1,3,4,5,6. However, for a magnetically ordered material the heavy bands must be polarized. Depending on the model and the strength of the polarization, this is expected to modify the Fermi surface towards the small one3,7,8 in which the 4f electrons are excluded from the Fermi volume. Thus, in the case of large ordered moments, many low-temperature properties, like for example, the Fermi surfaces or the Sommerfeld coefficient, do not reflect any more the bare hybridization, because its effect is masked by the strong polarization. This results in some ambiguity in characterizing the nature of the 4f electrons in such systems7. The entanglement between 4f and valence states in such systems has not been deeply addressed in the past, but is now becoming an important and pressing issue, for example, because of the observation of metamagnetic transitions with huge changes in the Fermi surface in quite a number of compounds located in this regime, and with controversial interpretations (see for example, refs 9, 10).

CeRh2Si2 is a system where the ambiguity in the nature of the 4f electrons is particularly striking11. On one hand, its high antiferromagnetic ordering temperature12, TN≈38 K, being the third highest among Ce systems; its large ordered moment mAF≈1.4μB (refs 12, 13), and most especially its large entropy of nearly Rln2 at TN (ref. 14) are strong evidence for a fully localized 4f electron. Accordingly, de Haas van Alphen (dHvA) experiments15 reported the observation of a small Fermi surface. On the other hand, other properties like for example, the width of the quasi-elastic line in inelastic neutron scattering16,17 imply a large Kondo scale of the order of TK30 K. Furthermore, the transition to a paramagnetic ground state at a comparatively small pressure pc≈1.1 GPa (ref. 18) indicates a close proximity of the 4f state to a magnetic instability. The large TK and the small pc indicate a significant hybridization of the 4f electrons. However, in CeRh2Si2 magnetism wins over Kondo at ambient pressure, and therefore the effect of this large hybridization on low-T properties gets masked, making a study and an assessment of this hybridization difficult.

Here we study the single particle spectrum of the Ce 4f electronic states in the antiferromagnetic (AFM) Kondo lattice CeRh2Si2 by means of high-resolution angle-resolved photoelectron spectroscopy (ARPES). Generally, the Ce 4f photoemission spectroscopy (PES) spectrum shows a characteristic double-peak structure with one peak at about 2 eV binding energy (BE) corresponding roughly to the 4f0 final state configuration as expected from the ionization of the trivalent 4f1 ground state, and a second feature at EF, commonly ascribed to the tail of the Kondo resonance that is centered slightly above EF (refs 1, 19). Theoretically, this spectral function is well-understood and well-described within the Kondo and Anderson lattice models. The 2-eV feature, which carries most of the 4f spectral weight, reflects the localized, ionization-like aspect of the Ce 4f, while the weaker feature at EF reflects the hybridized, quasi-particle aspect. However, a precise experimental confirmation of all expected features faced strong problems connected with differentiating between surface and bulk electronic contributions1. So far, however, poorly defined surfaces have resulted in a mixture of surface- and bulk-related signals in ARPES, preventing a precise analysis and assignment. High-energy PES strongly enhances the bulk part of the signal, but the much poorer energy resolution prevents the detection of fine structures, in particular close to EF. Taking advantage of our expertize gained in the course of extended ARPES studies on the homologues YbRh2Si2 and EuRh2Si2, we were able to obtain spectra for the Ce-terminated and the Si-Rh-Si terminated surfaces of CeRh2Si2, which are representative for weakly and strongly hybridized 4f states, respectively. Comparing both spectra provides an unprecedented view into the effects of f−d hybridization on the electronic spectral function, revealing features such as a CEF induced fine structure near the Fermi edge for the Si−Rh−Si surface. For this surface, which is representative for bulk CeRh2Si2, we observe a strong interaction between valence and f electrons at a temperature well below TN, which demonstrates the importance of hybridization effects in the antiferromagnetic phases of Kondo lattices.

Results

Si- and Ce-surface termination of CeRh2Si2 viewed by ARPES

We begin with a general characterization of different surface terminations of cleaved CeRh2Si2 crystals. Our previous ARPES studies on structurally similar RET2Si2 materials (RE=Eu, Yb and T=Co, Rh, Ir) demonstrated that cleavage always takes place between Si and RE layers leaving behind either a RE or a Si terminated surface20,21,22,23,24. The covering of a RE plane with a Si−Rh−Si trilayer is usually sufficient to create a bulk-type chemical surrounding for the RE ions25,26. The Si-terminated surface of cleaved CeRh2Si2 may thus be used to evaluate the bulk contribution of the Ce 4f spectrum. For the Ce-terminated surface, however, the ARPES spectra are dominated by emissions from the outermost Ce layer and give information about the surface properties of Ce in CeRh2Si2. We also utilize two PES cross-section effects, a Fano resonance enhancement of the Ce 4f emission for photon energies around 121 eV, corresponding to the Ce 4d→4f X-ray absorption edge1, and a Cooper minimum suppression21 of the Rh 4d emission, coincidentally also around 121 eV.

Figure 1a,b shows two off-resonance ARPES-derived band maps taken from a freshly cleaved CeRh2Si2 crystal close to the direction. These data reflect the discussed surface configurations: Si and Ce terminations can be distinguished by the presence/absence of a Shockley-type surface state labelled by star symbols. This state emerges within a huge gap in the projected bulk band structure centered at the - point and is an intrinsic feature of the Si surface. Note that this spectral feature stems mainly from Si 3s, 3p and Rh 4d hybrid states, and was the focus of our earlier studies of the unusual ferromagnetic properties of the Si surface in EuRh2Si2 (ref. 24). Located within the topmost Si−Rh−Si trilayer, this surface state is missing in the Ce-terminated case, where the respective electrons participate in chemical bonds with the topmost Ce layer. In contrast to EuRh2Si2, the - point Shockley state does not seem to split down to a temperature of 1 K, even though the system is in its AFM phase27,28,29. This might be a consequence of the robust in-plane AFM order of the Ce moments along each Ce layer—in contrast to the ferromagnetic arrangement of the 4f moments within the Eu planes in EuRh2Si2—canceling the exchange interaction between the Ce moments and the electrons in the surface state. A further signature of differing surface terminations shows up in a hole-like, linearly dispersing surface resonant band labelled by a sun-symbol around the point in the Si-terminated case22,23, which is replaced by an intense, rocket-shaped feature (labelled by a triangle) below 0.5 eV BE for Ce termination. The Dirac cone (sun-symbol) arises from Rh 4d states in the topmost Si−Rh−Si trilayer and has similarly been found in YbRh2Si2 and EuRh2Si2 (refs 21, 22, 23). Note also that for the Ce-terminated surface we detect the fine structure (marked by a diamond symbol) close to EF, which will be discussed below.

Figure 1: ARPES characterization of different surface terminations.
figure 1

ARPES data of (a) Si and (b) Ce terminated surfaces of CeRh2Si2 are shown in a 2D view where yellow (red) denotes the largest intensity. The data along the direction were taken at 112 eV photon energy (off resonance) and reveal mainly contributions from spd-derived bands. For the meaning of the symbols see the main text.

4f spectrum for Ce atoms at the surface and in the bulk

Tuning the photon energy towards 121 eV, strong contributions from Ce 4f emissions are expected. A series of three spectra ranging from off to on resonance for each surface termination, respectively, is shown in Fig. 2. For Ce termination (Fig. 2a), emission from Rh 4d states dominating the off resonance spectra is strongly suppressed by the Cooper minimum and replaced by the resonantly enhanced Ce 4f emission at 121 eV photon energy. The non-dispersive structure at about 1.9 eV BE and the flat spectral feature close to EF are intensified indicating their Ce 4f origin. For Si termination (Fig. 2b), Rh 4d emission is similarly reduced, but now three flat bands appear right below EF, which did not show in the off resonance spectrum. These flat bands can be attributed to 4f emission from the bulk-type Ce layer buried beneath the Si−Rh−Si covering. The fine structure of the bulk Ce 4f emission consists of a spin-orbit side band at0.3 eV BE corresponding to the Ce 4f17/2 final state1 and weakly dispersive bands packed within tens of meV below EF.

Figure 2: Insight into the Ce 4f spectral evolution for Ce- and Si-terminated CeRh2Si2.
figure 2

ARPES-derived band maps for (a) a Ce-terminated surface along and (b) a Si-terminated surface along directions are shown taken at photon energies of 114, 118 and 121 eV. The data illustrate the evolution of momentum resolved Ce 4f emissions across the Ce 4d–4f threshold. Angle-integrated spectra taken at 121 eV photon energy for both surfaces are presented in c,d. Dotted rectangles draw attention to the 4f15/2 peaks.

The aforementioned spin-orbit sideband shows up for Ce termination as well. The intense 4f feature at EF, however, does not show a similar splitting as observed for the Si termination. The latter is nicely seen in the angle-integrated spectra shown in Fig. 2c,d, obtained by summing up the k-distributed spectral weight of the on-resonance data. These features lie within the dotted rectangles. As will be discussed below, the splitting seen in the Si-terminated data is the CEF splitting of the Ce 4f15/2 sextet under D4h symmetry. It is interesting to note that large intensities of the EF peak are restricted to a narrow region around the point at the Ce-terminated surface. A similar, but less pronounced, phenomenon is also observed for Si-termination. Large intensity of the EF peak denotes strong fd hybridization and the latter is particularly large at points in k space where valence bands approach or even cross EF (refs 21, 22). This is nicely reflected in the data for the Si-terminated surface where the EF peak intensity increases just below the EF crossing of a band close to the point. The large intensities around the point may, thus, be attributed predominantly to hybridization with the apex of the Dirac cone. We note that the apparent sizeable f1 spectral weight in the ‘bulk’ spectra does not correspond to a large departure of the expectation value of the 4f occupancy nf from the integer value 1. X-ray absorption spectroscopy measurements, which provide the most reliable information, determine an nf of the order of 0.975, but this small decrease in nf is typical for systems close to the transition from localized to itinerant 4f states, as for example, in CeCu2Si2 with nf=0.97 (ref. 17).

The broader peak emerging at 1.9 eV BE for Ce termination deserves particular attention. It arises from pure charge excitations of the trivalent Ce ion (4f1→4f0), and is usually referred to as the ionization peak30,31. A shoulder of this peak observed at 2.4 eV BE in the k-integrated spectrum reflects hybridization spreading due to structure in the valence band density of states. For Si termination, the intensity of the ionization peak is strongly reduced relative to the emissions close to EF and consists of a broad bump at 1.5 eV BE, again with a shoulder due to hybridization spreading. The large intensity of the Fermi level peaks with respect to the ionization peak is indicative of strong fd hybridization, much larger than that in the Ce surface layer, and is also reflected by the dispersive properties of the ionization peak in the k-resolved data. The larger BE of the leading ionization peak for the Ce-terminated surface is due to the surface-core-level shift, which is on the order of 0.4 eV for trivalent rare-earth systems, in good agreement with the shift of the peak from 1.5 to 1.9 eV observed here. Interestingly, the difference in the ionization peak signal between the weakly hybridized surface spectra and the stronger hybridized bulk spectra is very similar to the difference predicted for the f states within LDA+DMFT between CeFeAsO (weak hybridization) and CeFePO (strong hybridization)32.

In Fig. 3, we take a closer look at the fine Ce 4f spectral structure near the -point. For the Si-terminated surface (Fig. 3a), two prominent features can be seen. An intense and weakly dispersive band bending down to 20 meV BE near the - point and a heart-shaped feature, which indicates hybridization of the Dirac cone apex with CEF 4fs running parallel to EF and packed in a 50 meV range (Fig. 2b). The weakly dispersive band close to EF is similarly found for Ce termination as shown in Fig. 3b except that the heart feature is missing. Since CeRh2Si2 is AFM ordered at the experimental temperature, we interpret non-zero BE as a characteristic feature arising due to the magnetically ordered ground state of the Ce 4f electrons33. Although appendix F in ref. 33 treats a ferromagnetic ground state, the underlying concept for a Kondo peak away from EF should be valid also for an AFM. Note that the magnetically ordered ground state is separated from the Kondo resonant state by an energy corresponding to the stabilization of the magnetic state (TN3 meV for CeRh2Si2). Consequently, a PES feature appears just below EF carrying a large weight due to the degeneracy of the Ce 4f orbital33.

Figure 3: Fine electronic structure for Si and Ce surface terminations.
figure 3

ARPES spectra of the Ce 4f -derived states close to the EF and near the point taken in on-resonance for (a) Si and (b) Ce terminated surfaces are shown. ARPES data taken at Ce terminated surfaces in off -resonance are shown for comparison (c). The heart-shaped feature results from the hybridization of the CEF split Ce 4f states and the apex of the Dirac cone.

In the off-resonance spectrum (Fig. 3c), where 4f emission is suppressed and the spectrum is dominated by valence-band emission, a similar feature is visible. This indicates the important role of Rh valence-band states in the formation of the fine spectral structure close to EF. Similar dispersions and EF crossings of 4f-derived quasiparticle bands have already been observed in YbRh2Si2 (ref. 22) and CeFePO as well34.

ARPES insight into the CEF splittings of 4f1 state

Let us turn now to the discussion of the 4f CEF splittings detected by ARPES. We first note that according to standard theoretical modelling of PES on Kondo lattices1, the physics behind the CEF split lines in Ce- systems is quite different from that in Yb systems: In Yb-compounds, the 4f13 final state is predominantly a result of a direct ionisation of a 4f14 configuration admixed to the 4f13 ground state. The amount of this admixture could be estimated from the relative intensity of the 4f13 emission normalized to the whole 4f emission, and a more precise calculation within the Anderson model deviates only slightly from this result. In the Ce-compound, however, the admixture of 4f2 configurations to the ground state are rather small, and the 4f1 emission originates mostly from strong hybridization of 4f1 and 4f0 configurations. Thus, while in the Yb-system the intensity of the crystal-field PES signal is governed by the atomic dipole matrix elements, in Ce-systems its observability reflects its participation in the hybridization process. Accordingly, if the CEF states were not hybridized, then the photoemission spectral function would still show CEF satellites for an Yb valence fluctuating system, but no satellites for a homologue Ce system. Therefore, the observability of the CEF split state in CeRh2Si2 provides on its own a direct evidence for the hybridization of the excited CEF levels.

In Fig. 4a, we show the ARPES data taken at 40 eV photon energy using circularly polarized light from the Si-terminated surface of CeRh2Si2. These experimental conditions allow us to clearly detect both 4f and valence band emission together, while still giving good contrast between them. Thus, we can conclusively identify the k space regions where the CEF states reveal their dispersive and non-dispersive behaviours. For each k value the spectra were normalized to constant integrated emission intensity in the BE range from 30 to 70 meV. We also show the k-integrated spectrum taken from region C. The ARPES data clearly show strongly dispersing hole-like bands, which stem mainly from Rh 4d-derived states. Also, we can see two states A and B that run parallel to EF and reveal weak dispersions at points in k space where the valence bands approach them and hybridize. Apparently, the mentioned peak A at 48 meV and peak B at 62 meV BE reflect the fine structure of the 4f states. Approaching the - point the component A disperses towards lower BE, due to its interaction with the Rh hole-like band, reaching about 30 meV exactly at , while component B seems to disperse in the opposite direction. The appearance of two components is in accordance with the expected CEF splitting in the tetragonal environment of D4h point group symmetry, where the ground state Ce 4f15/2 splits into three Kramers doublets. Note that the ARPES data show certain fd hybrid states that are packed between the ground state (0 meV) and the first excited CEF state (48 meV). Because the CEF split states have identical degeneracy, one may anticipate that the integrated spectral weight of all the CEF split states should be same. However, from Fig. 4 it can be seen that the feature A is more intense as compared with the other states. An apparent explanation for this difference is that the feature B and the fd hybrid states below 48 meV are connected and that their strong dispersion due to hybridization with Rh 4d redistributes their spectral weights over a much larger energy window than that of feature A. Thus, the fine structure that we observe in the ‘4f1’ spectra indicates that one of the excited CEF doublets is strongly hybridized, while the other one is less hybridized. Notably, a recent theoretical calculation predicts the hybridization for the Γ6 doublet in CeRh2Si2 to be much weaker than for the Γ7 doublets35. Since all present experimental and theoretical studies indicate one of the Γ7 to be the CEF ground state and Γ6 to be at a comparatively high energy, all these observations can then be merged in a picture with a weakly hybridized Γ6 at 48 meV and a strongly hybridized Γ7 distributed in a wide energy range up to about 65 meV. Previous studies of the CEF scheme are far from being conclusive. Early determinations based on the temperature dependence of the magnetic susceptibility have suggested CEF level schemes of 0–32–80 meV (ref. 27) and 0–27–59 meV (ref. 28) with an almost pure |+/−5/2〉 CEF ground state. The most recent study is based on inelastic neutron scattering (INS) and X-ray-absorption spectroscopy17 and proposes a level scheme of 0–30–52 meV with a strong mixing of |+/−5/2〉 and |−/+3/2〉 in the ground state, which is incompatible with the measured susceptibility and magnetization data27,28. While INS is usually a proven technique to determine the CEF excitation energies, in CeRh2Si2 it revealed a very broad response, extending up to 60 meV, without well-resolved peaks, making the separation between phonon and magnetic excitations far from evident17. This broadness of the CEF response in INS is in line with the wide spectral distribution observed for the feature B and the fd hybrid states in the PES 4f1 signal. The PES results provide direct insight into the origin for this broadness, namely a strong hybridization with the Rh 4d states. On the other hand, assuming the A features in PES to correspond to the Γ6 doublet, we note that the INS cross section for the transition from a dominantly |+/−5/2〉 CEF ground state to the Γ6 excited state is comparatively small, thus the sharper peak expected in INS for this transition might be absorbed within the broad response related to the Γ7–Γ7 transition.

Figure 4: CEF splitting of the Ce 4f state and the hybridization phenomenon.
figure 4

(a) The ARPES data taken from the Si-terminated surface of CeRh2Si2 using 40 eV photons. Note that asymmetry of the cross-sections with respect to the point is caused by the use of circularly polarized light. Each ARPES spectrum was normalized to the region labelled D between 30 and 70 meV BE, so that the integrated intensity for each energy distribution curve (EDC) is equal in this range. The line spectrum (b) was obtained by angle integration of EDCs within the shaded region labelled C. Its fit allows to deduce the CEF scheme: 0–48–62 meV. Note the fine dispersions of the CEF states visible between EF and 50 meV. The ARPES spectrum taken at the point marked as a dotted line in (a) is shown in (c).

An established method to check the relevant energy scales of a Kondo lattice, that is, TK and the CEF splitting, is to study the evolution of the 4f-specific heat C4f (T) and 4f entropy S4f (T) as a function of T (refs 36, 37). Usually one gets reasonable agreement between the experimental C4f (T) and that calculated using parameters obtained from other methods. As an example, we could recently very nicely reproduce the experimental C4f (T) of YbIr2Si2 using the CEF splitting deduced from the ARPES spectra, and thus demonstrate that INS missed the highest CEF level26. Therefore, we determined C4f (T) and S4f (T) of CeRh2Si2 in a wide T range, up to 300 K, and compared with the curves expected for different CEF schemes and different values of the Kondo temperature TK (Fig. 5)38. There is presently no analytical expression available for the specific heat of a Kondo lattice which includes both AFM order and the Kondo effect on the excited CEF levels. Since in the present study we are specifically interested in the excited CEF levels, we focus on C4f (T) and S4f (T) above TN. In the standard way of modelling C4f (T) the contribution of the excited CEF level is accounted for by a simple Schottky expression and thus broadening of the CEF levels due to the Kondo effect is not taken into account (see section methods). Since in CeRh2Si2 INS results evidence a significant broadening of the CEF levels, in line with the present PES results, we preferred to use the recent model of Romero et al.37, where the broadening of the first excited level can be taken empirically into account. We initially performed two calculations, one with the CEF excitation energies Δ1 and Δ2 as deduced from INS17, and one with Δ1 and Δ2 as deduced from the present ARPES results. In both cases we took TK and width Γ1 of the first excited CEF level as deduced from INS17. Including AFM order would modify C4f (T) and reduce S4f (T) only in the T range from slightly above TN to T=0. Above TN, the agreement between the experimental curve and the curve for the CEF scheme deduced from INS is not too bad, while the curve for the ARPES deduced CEF scheme is too much shifted towards high temperatures. However, in both cases the maximum connected with the CEF excitations is much narrower in the theoretical C4f (T) curves than in the experimental ones, suggesting that the width of the CEF level has been underestimated in the analysis of the INS data. A more fundamental problem is that in both cases the calculated 4f entropy in the T range 50 K<T<100 K is significantly smaller than the experimental one. In an attempt to resolve this discrepancy, we first reduced TK by one order of magnitude. The entropy above TN is now nicely reproduced, but C4f (T) is now severely underestimated in the T range 50 K<T<100 K. Increasing the width of the first excited CEF doublet does not correct this discrepancy. Furthermore such a low TK is incompatible with many other properties, for example, the width of the quasi-elastic line in INS and strong hybridization seen in the bulk ARPES signal.

Figure 5: Insight into the specific heat and entropy of the Ce 4f.
figure 5

Temperature dependence of the 4f specific heat (a) and of the 4f entropy (b) in CeRh2Si2. Black dots show the values deduced from experiment. Coloured lines show the curves calculated for different values of the CEF splitting Δ1 and Δ2, of the Kondo scale TK, and of the width Γ1 of the first excited CEF level, using the model of Romero et al.37 or the numerical results of Desgranges38. This approach does not include AFM ordering, therefore, comparison with experiment is only meaningful for T>50 K. Parameter values are given in meV in the figure. Blue diamonds: values as deduced from INS. Magenta stars: same as before, but with Δ1 and Δ2 taken from our PES results. Red triangles: Parameter as deduced from INS, but with TK reduced by a factor of 10 to account for the observed entropy at 50 K. Green circles: same as before, but with Γ1 increased by a factor of 3 in an attempt to reproduce the observed large Cp(T) for 40<T<100 K despite a low TK. Brown triangles: scaled numerical results of Desgranges38. It corresponds to the case Δ1=35 meV, Δ2=70 meV and TK=2.6 meV.

The specific heat of a Kondo ion including CEF splitting (with same hybridization strength for ground and excited CEF states) can be calculated exactly in the single ion case, but this requires very demanding numerical calculations which do not allow for ‘fitting’ experimental data. Fortunately, Desgranges38 very recently provided such numerical results for a larger number of cases, and therefore we tried to use them for modelling our experimental C4f (T) data. In this approach, one has first to choose the most appropriate case among those considered in ref. 38, and then to fix the only free parameter which is the Kondo scale in the absence of CEF splitting, TKN6. A preliminary survey of the results in ref. 38 suggests that the curve for Δ1=1/2˙Δ2=0.7·TKN6 is closest to our experimental data. Matching experimental and calculated C4f (T) in the T range 50<250 K resulted in TKN6=50 meV. This corresponds to a Kondo scale TK=2.6 meV for the ground-state doublet and to CEF splitting of Δ1=35 meV and Δ2=70 meV. The agreement between calculated and experimental specific heat data in the T range 50 K<T<250 K is excellent (Fig. 5). A slightly poorer agreement is obtained for the case Δ12=TKN6=43 meV (not shown), corresponding to TK=2.3 meV. However, in both cases the calculated entropy in the T range 50 K<T<100 K is significantly smaller than the experimental values, reflecting the same problem as for the fits with the model of Romero et al. The essence of this problem is that in the case of a CEF ground-state doublet well-separated from the excited CEF states due to a large splitting as in CeRh2Si2, the large Kondo interaction implied by other properties, like for example, the broadening of the CEF contribution to C4f (T) or the (bulk) ARPES response, always reduces the entropy at 40 K significantly below Rln2. Resolving this problem requires considering further interactions beyond the single-ion Kondo and the CEF splittings.

Despite this intricate problem, the analysis of C4f (T) supports our analysis of the bulk part of the ARPES signal. The broadness of the CEF contribution to C4f (T) at high T implies a strong hybridization of the bulk 4f states, in line with our conclusion from the bulk PES signal, and in line with other properties. This shows CeRh2Si2 to be strongly hybridized even though it has fully localized 4f electrons in the sense of the large size of the AFM ordered moment, the large entropy at TN, and the small Fermi surface deduced from dHvA experiments15. The comparison of experimental C4f (T) with exact numerical results for the Kondo+CEF single-ion model indicates the broadening of the excited CEF level to be even larger than the value deduced from INS results, but of the size expected when the hybridization of the CEF ground and excited states are identical. This suggests that in previous similar studies the broadening of the excited CEF states might have been underestimated. On the other hand, the analysis of C4f (T) is not conclusive with respect to the exact CEF splitting, but supports a large value of this splitting, of the size we observed in the bulk ARPES signal.

In summary, we have presented an ARPES study of the antiferromagnetic Kondo lattice CeRh2Si2 which provides precise insight into how the hybridization between valence and f electrons affects the Ce 4f PES response. We discern two well-defined and different types of spectra, which we can clearly connect with the Si- and Ce-terminated surfaces of CeRh2Si2. The latter, which is representative for weakly hybridized Ce, shows a strong and sharp 4f0 peak at 1.9 eV BE, and a structureless peak at the Fermi energy. In the Si-terminated surface, which is representative for bulk-type Ce, the strong hybridization between Ce 4f and Rh 4d electrons essentially suppresses the 4f0 signal and induces momentum dependent fine structure just below the Fermi level, which reflects the crystal electric field splitting of the magnetic 4f1 configuration. These results likely represent the exemplary PES response expected for a Ce-based magnetic Kondo lattice. The fine structure as observed in CeRh2Si2 indicates the following. First, there is a weakly hybridized excited CEF level at 48 meV. Second, there is a state around 62 meV, but which is spread over a large energy range due to strong hybridization and third, there is a strongly dispersive band stemming from the Γ7 ground state.

More importantly, the fact that we observed the CEF satellites in the PES signal taken at T1 K<TN proves that even in the large moment AFM ordered state there is a significant mixing between the f1 and the f0 state, despite the observation of a small Fermi surface apparently without f degree of freedom in dHvA experiments. Thus our ARPES results provide important information on the entanglement between 4f and valence states in an AFM-ordered Kondo lattice systems, which is likely difficult to get by other kinds of measurements.

Methods

ARPES measurements

ARPES studies were performed at the 13 ARPES instrument of the BESSY-II synchrotron facility. The spectra were acquired using a Scienta R4000 electron energy analyzer. The overall energy and angular resolutions were set to 6 meV and 0.1, respectively. High-quality single-crystalline samples of CeRh2Si2 were cleaved in situ in ultrahigh vacuum at a base pressure better than 8 × 10−11 mbar. The sample was kept at a temperature of 1 K during the measurements. The photon energy was varied to take advantage of a resonant enhancement of the 4f emission cross-section at the Ce 4d–4f excitation threshold at 121 eV.

Sample preparation and specific heat measurements

Single crystals were grown by the in-flux technique following the procedure described in detail in ref. 39. Polycrystalline CeRh2Si2 and LaRh2Si2 samples were prepared by arc melting of the constituent elements under a high-purity Argon atmosphere. As-cast ingots were annealed for 2 days at 1,200 °C under high vacuum. Chemical composition, crystal structure, and physical properties of single crystals and polycrystals were checked by microprobe, X-ray diffraction and resistivity measurements, respectively. Specific-heat measurements were performed on polycrystalline samples of CeRh2Si2 and LaRh2Si2 using the standard specific heat option of the physical property measurement system, Quantum Design, USA. LaRh2Si2 is here taken as reference compound for subtracting the non-f part of the specific heat, that is, the phonon and the non-f electron contributions. Since at high temperatures the 4f contribution is tiny compared to the phonon part, special care was taken to get accurate absolute values. Both the CeRh2Si2 and the LaRh2Si2 samples were measured under identical conditions. For each sample, we determined in a first run the addenda (platform and grease) and then in a second run the total specific heat (addenda+sample). The whole procedure was repeated with a different part of the polycrystalline batches in order to get two independent sets of data. Both sets agreed very nicely, and the 4f specific-heat deduced from the these two data sets differ by <0.4 J mol–1 K–1 in the whole T range up to 300 K. The magnetic entropy S4f was determined by numerically integrating C4f/T and using a liner extrapolation for the T range below 2 K.

We used the analytical expression of Romero et al.37 to generate C4f and S4f for different CEF schemes (Δ1 and Δ2 energy of excited levels) and different values of the Kondo temperature (TK) and width of the first excited CEF level (Γ1). The values for the different parameters were chosen on the basis of previous and present experimental results (see main text). Desgranges provided us with his numerical results for the Kondo+CEF model for the cases A2=A4=0.7 TKN6 and A4=0, A2=TKN6 (nomenclature as in ref. 38), which correspond to the cases Δ2=2·Δ1 and Δ21, respectively. TKN6 was scaled in order to get the best match for the specific heat data. TK (for the ground state doublet) was calculated from TKN6 by combining the numerical result lim(C/R·TKN6/T)T→020.0 and the definition lim(C/T)T→0=R·π/(3TK)38.

Additional information

How to cite this article: Patil, S. et al. ARPES view on surface and bulk hybridization phenomena in the antiferromagnetic Kondo lattice CeRh2Si2. Nat. Commun. 7:11029 doi: 10.1038/ncomms11029 (2016).