## Abstract

A paradigmatic case of multi-band Mott physics including spin-orbit and Hund’s coupling is realized in Ca_{2}RuO_{4}. Progress in understanding the nature of this Mott insulating phase has been impeded by the lack of knowledge about the low-energy electronic structure. Here we provide—using angle-resolved photoemission electron spectroscopy—the band structure of the paramagnetic insulating phase of Ca_{2}RuO_{4} and show how it features several distinct energy scales. Comparison to a simple analysis of atomic multiplets provides a quantitative estimate of the Hund’s coupling *J*=0.4 eV. Furthermore, the experimental spectra are in good agreement with electronic structure calculations performed with Dynamical Mean-Field Theory. The crystal field stabilization of the *d*_{xy} orbital due to *c*-axis contraction is shown to be essential to explain the insulating phase. These results underscore the importance of multi-band physics, Coulomb interaction and Hund’s coupling that together generate the Mott insulating state of Ca_{2}RuO_{4}.

## Introduction

Electronic instabilities driving superconductivity, density wave orders and Mott metal–insulator transitions produce a characteristic energy scale below an onset temperature^{1,2,3}. Typically, this energy scale manifests itself as a gap in the electronic band structure around the Fermi level. Correlated electron systems have a tendency for avalanches, where one instability triggers or facilitates another^{4}. The challenge is then to disentangle the driving and secondary phenomena. In many Mott insulating systems, such as La_{2}CuO_{4} and Ca_{2}RuO_{4}, long-range magnetic order appears as a secondary effect. In such cases, the energy scale associated with the Mott transition is much larger than that of magnetism. The Mott physics of the half-filled single-band 3*d* electron system La_{2}CuO_{4} emerges due to a high ratio of Coulomb interaction to band width. This simple scenario does not apply to Ca_{2}RuO_{4}. There the orbital and spin degrees of freedom of the 2/3-filled (with four electrons) *t*_{2g}-manifold implies that Hund’s coupling enters as an important energy scale^{5}. Moreover, recent studies of the antiferromagnetic ground state of Ca_{2}RuO_{4} suggest that spin–orbit interaction also plays a significant role in shaping the magnetic moments^{6,7,8}, as well as the splitting of the *t*_{2g} states^{9}.

Compared to Sr_{2}RuO_{4} (refs 10, 11), which may realize a chiral *p*-wave superconducting state, relatively little is known about the electronic band structure of Ca_{2}RuO_{4} (ref. 12). Angle integrated photoemission spectroscopy has revealed the existence of Ru states with binding energy 1.6 eV (ref. 13)—an energy scale much larger than the Mott gap ∼0.4 eV estimated from transport experiments^{14}. Moreover, angle-resolved photoemission spectroscopy (ARPES) experiments on Ca_{1.8}Sr_{0.2}RuO_{4}—the critical composition for the metal–insulator transition—have led to contradicting interpretations^{15,16} favouring or disfavouring the so-called orbital-selective scenario where a Mott gap opens only on a subset of bands^{17,18}. Extending this scenario to Ca_{2}RuO_{4} would imply orbital-dependent Mott gaps^{18}. The electronic structure should thus display two Mott energy scales (one of *d*_{xy} and another for the *d*_{xz}, *d*_{yz} states). A different explanation for the Mott state of Ca_{2}RuO_{4} is that the *c*-axis compression of the S-Pbca insulating phase induces a crystal field stabilization of the *d*_{xy} orbital, leading to half-filled *d*_{xz}, *d*_{yz} bands and completely filled *d*_{xy} states^{19,20}. In this case, only one Mott gap on the *d*_{xz}, *d*_{yz} bands will be present with band insulating *d*_{xy} states. The problem has defied a solution due to a lack of experimental knowledge about the low-energy electronic structure.

Here we present an ARPES study of the electronic structure in the paramagnetic insulating state (at 150 K) of Ca_{2}RuO_{4}. Three different bands—labelled , and band—are identified and their orbital character is discussed through comparison to first-principle Density Functional Theory (DFT) band structure calculations. The observed band structure is incompatible with a single insulating energy scale acting uniformly on all orbitals. A phenomenological Green’s function incorporating an enhanced crystal field and a spectral gap in the self-energy is used to describe the observed band structure on a qualitative level. Further insight is gained from Dynamical Mean-Field Theory (DMFT) calculations including Hund’s coupling and Coulomb interaction. The Hund’s coupling splits the *d*_{xy} band allowing quantitative estimate of this parameter. The Coulomb interaction is mainly responsible for the insulating behaviour of the *d*_{xz}, *d*_{yz} bands. The experimental results, together with our theoretical analysis, clarify the origin of the Mott phase in the multi-orbital system Ca_{2}RuO_{4}. Furthermore, they provide a natural explanation as to why previous experiments have identified different values for the energy gap.

## Results

### Crystal and electronic structure

Ca_{2}RuO_{4} is a layered perovskite, where the Mott transition coincides with a structural transition at *T*_{s}∼350 K, below which the *c*-axis lattice constant is reduced. We study the paramagnetic insulating state (*T*=150 K) of Ca_{2}RuO_{4} with orthorhombic S-Pbca crystal structure (*a*=5.39 Å, *b*=5.59 Å and *c*=11.77 Å). It is worth noting that due to this nonsymmorphic crystal structure, Ca_{2}RuO_{4} could not form a Mott insulating ground state at other fillings than 1/3 and 2/3 (ref. 21). In Fig. 1, the experimentally measured electronic structure is compared to a first-principle DFT calculation of the bare non-interacting bands. We observe two sets of states: near the Fermi level the electronic structure is comprised of Ru-dominated bands, while oxygen bands are present only for =*E*−*E*_{F}<−2.5 eV. Up to an overall energy shift, good agreement between the calculated DFT and observed Ca_{2}RuO_{4} oxygen band structure is found.

### Non-dispersing ruthenium bands

The structure of the ruthenium bands near the Fermi level is the main topic of this paper, as these are the states influenced by Mott physics. A compilation of ARPES spectra, recorded along high-symmetry directions, is presented in Figs 2 and 3a. In consistency with previous angle-integrated photoemission experiments^{13}, a broad and flat band is found around the binding energy =−1.7 eV. However, we also observe spectral weight closer to the Fermi level (∼−0.8±0.2 eV), especially near the zone boundaries (see Fig. 2a,d). These two flat ruthenium bands (labelled and ) are revealed as a double peak structure in the energy distribution curves—Fig. 2c,f. Between the band and the Fermi level, the spectral weight is suppressed. In fact, complete suppression of spectral weight is found for −0.2 eV<<0 eV (see Fig. 2c). This energy scale is in reasonable agreement with the activation energy ∼0.4 eV extracted from resistivity experiments^{14}.

### Fast dispersing ruthenium bands

In addition to the flat and bands, a fast dispersing circular-shaped band is observed (Fig. 3b) around the Γ-point (zone centre) in the interval −2.5 eV<<−2 eV—see Figs 2a,b and 3a. A weaker replica of this band is furthermore found around Γ_{2} (Fig. 3a,b). The band velocity, estimated from momentum distribution curves (Fig. 2a), yields *v*=(2.6±0.4) eV Å. As this band, which we label , disperses away from the zone centre, it merges with the most intense flat band. From the data, it is difficult to conclude with certainty whether the band disperses between the and bands. As this feature is weak in the spectra recorded with 78 eV photons (Fig. 2b), it makes sense to label and as distinct bands.

### Orbital band character

Next we discuss the orbital character of the observed bands. As a first step, comparison to the band structure calculations is made. Although details can vary depending on exact methodology, all band structure calculations of Ca_{2}RuO_{4} find a single fast dispersing branch^{22,23,24,25}. Our DFT calculation reveals that the fast dispersing band has predominantly *d*_{xy} character (Fig. 4a). We thus conclude that the in-plane extended *d*_{xy} orbital is responsible for the band. Within the DFT calculation, the *d*_{xz} and *d*_{yz} bare bands are relatively flat throughout the entire zone. This is also the characteristic of the observed band. It is thus natural to assign a dominant *d*_{xz}, *d*_{yz} contribution to this band. The orbital character of the band is not obviously derived from comparisons to DFT calculations. In principle, photoemission matrix element effects carry information about orbital symmetries. As shown in Fig. 2, the band displays strong matrix element effects as a function of photon energy and photon polarization. However, probing with 65 eV light, the spectral weight of the band is not displaying any regularity within the (*k*_{x}, *k*_{y}) plane—see Supplementary Fig. 1. The contrast between linear horizontal and vertical light therefore vary strongly with momentum. This fact precludes any simple conclusions based on matrix element effects.

## Discussion

Having explored the orbital character of the electronic states, we discuss the band structure in a more general context. Bare band structure calculations, not including Coulomb interaction, find that states at the Fermi level have *d*_{xy} and *d*_{xz}/*d*_{yz} character (see Fig. 4a). Including a uniform Coulomb interaction *U* results in a single Mott gap acting equally on all orbitals. Generally, this produces one single flat band inconsistent with the observation of two distinct flat bands ( and ). Adding in a phenomenological manner orbital-dependent Mott gaps to the self-energy produces two sets of flat bands. For example, one can introduce Δ_{xy}=0.2 eV and Δ_{xz,yz}=1.5 eV to mimic the and bands. However, such Mott gaps are not shifting the bottom of the fast V-shaped dispersion to the observed position. Better agreement with the observed band structure is found, when a Mott gap Δ_{xz,yz}=1.55 eV is added to the self-energy of the *d*_{xz}, *d*_{yz} states and a crystal field-induced downward shift Δ_{CF}=0.6 eV of the *d*_{xy} states is introduced. As shown in Fig. 3c, this reproduces two flat bands and simultaneously positions correctly the fast dispersing band. From the fact that the bottom of the band is observed well below the band, we conclude that an—interaction enhanced—crystal field splitting is shifting the *d*_{xy} band below the Fermi level.

A similar structure emerges from DMFT calculations^{26} including *U*=2.3 eV and Hund’s coupling *J*=0.4 eV. The obtained spectral function (Fig. 3d) is generally in good agreement with the experimental observations (Fig. 3a). Both the and bands are reproduced with the previously assigned *d*_{xy} and *d*_{xz}, *d*_{yz} orbital character (Fig. 4b,c). The band is also present in the DMFT calculation around −0.5 eV<<0 eV. Even though it is not smoothly connected with the band, it has in fact *d*_{xy} character (Fig. 4b). By analysing the multiplet eigenstates (Fig. 4d) and electronic transitions in the atomic limit of an isolated *t*_{2g} shell, we can provide a simple qualitative picture of both observations: (i) the energy splitting between the and bands having *d*_{xy} orbital character, which we find to be of order 3*J*, and (ii) the *d*_{xz} and *d*_{yz} orbital-driven band splitting across the Fermi level, found to be of order *U*+*J*. Within this framework, the atomic ground state has a fully occupied *d*_{xy} orbital, while the *d*_{xz}, *d*_{yz} orbitals are occupied by two electrons with parallel spins (*S*=1) and thus effectively half-filled. The Mott gap developing in the *d*_{xz}, *d*_{yz} doublet is thus *U*+*J* in the atomic limit^{5}, corresponding to the electronic transition where one electron is either removed from this doublet or added to this doublet (leading to a double occupancy). In contrast, there are two possible atomic configuration that can be reached when removing one electron out of the fully filled *d*_{xy} orbital (Fig. 4d). One of these final states (high spin) has *S*=3/2, *L*=0 (corresponding pictorially to one electron in each orbital all with parallel spins), while the other (low spin) has *S*=1/2, *L*=2 (corresponding to the case when the remaining electron in the *d*_{xy} orbital has a spin opposite to those in *d*_{xz}, *d*_{yz}). The energy difference between these two configurations is 3*J*, thus accounting for the observed ARPES splitting between the two *d*_{xy} removal peaks. Furthermore, this analysis allows to assess, from the experimental value of this splitting ∼1.2 eV, that the effective Hund’s coupling for the *t*_{2g} shell is of the order of 0.4 eV. This is consistent with previous theoretical work in ruthenates^{27,28} and provides a direct quantitative experimental estimate of this parameter. Because the high spin state is energetically favourable with respect to the low spin state (by ∼3*J*), it can be assigned to the band near the Fermi level, while the low spin state can be assigned to the band (See ref. 5 for a detailed description of the atomic multiplets of the *t*_{2g} Kanamori Hamiltonian). The Hund’s coupling has thus profound impact on the electronic structure of the paramagnetic insulating state of Ca_{2}RuO_{4}. The fact that Hund’s coupling mainly influence the *d*_{xy} electronic states highlights orbital differentiation as a key characteristic of the Mott transition. Moreover, our findings emphasize the importance of the crystal field stabilization of the *d*_{xy} orbital^{19,20}. To further understand the interplay between *U* and *J*, detailed experiments through the metal–insulator transition of Ca_{2−x}Sr_{x}RuO_{4} would be of great interest.

## Methods

### Experimental

High-quality single crystals of Ca_{2}RuO_{4} were grown by the flux-feeding floating-zone technique^{29,30}. ARPES experiments were carried out at the SIS, I05 and MAESTRO beamlines at the Swiss Light Source, the Diamond Light Source and the Advanced Light Source. Both horizontal and vertical electron analyser geometry were used. Samples were cleaved *in situ* using the top-post cleaving method. All spectra were recorded in the paramagnetic insulating phase (*T*=150 K), resulting in an overall energy resolution of approximately 50 meV. To avoid charging effects, care was taken to ensure electronic grounding of the sample. Using silver epoxy (EPO-TEK E4110) cured just below *T*=350 K (inside the S-Pbca phase—space group 61) for 12 h, no detectable charging was observed when varying the photon flux.

### DFT band structure calculations

We computed electronic structures using the projector augmented wave method^{31,32} as implemented in the VASP^{33,34} package within the generalized gradient approximation^{35}. Experimental lattice constants (*a*=5.39 Å, *b*=5.59 Å and *c*=11.77 Å) and a 12 × 10 × 4 Monkhorst-Pack *k*-point mesh was used in the computations with a cutoff energy of 400 eV. The spin–orbit coupling effects are included self-consistently. In order to model Mott physics, we constructed a first-principles tight-binding model Hamiltonian, where the Bloch matrix elements were calculated by projecting onto the Wannier orbitals^{36,37}, which used the VASP2WANNIER90 interface^{38}. We used Ru *t*_{2g} orbitals to construct Wannier functions without using the maximizing localization procedure. The resulting 24-band spin–orbit coupled model with Bloch Hamiltonian matrix reproduces well the first-principle electronic structure near the Fermi energy. To model the spectral function, we added a gap with a leading divergent 1/*ω* term to the self-energy . To the Hamiltonian, we added a shift . and are projectors on the *d*_{xy} and *d*_{xz}, *d*_{yz} orbitals, respectively, while Δ_{xz,yz} is the weight of the poles and Δ_{CF} mimics an enhanced crystal field. From the imaginary part of the Green’s function with the two adjustable parameters Δ_{CF} and Δ_{xz,yz}, we obtained the spectral function *A*(* k*,

*ω*) by taking the trace over all orbital and spin degrees of freedom.

### DFT+DMFT band structure calculations

We calculate the electronic structure within DFT+DMFT using the full potential implementation^{39} and the TRIQS library^{40,41}. In the DFT part of the computation, the Wien2k package^{42} was used. The local-density approximation (LDA) is used for the exchange-correlation functional. For projectors on the correlated *t*_{2g} orbital in DFT+DMFT, Wannier-like *t*_{2g} orbitals are constructed out of Kohn–Sham bands within the energy window (−2, 1) eV with respect to the Fermi energy. We use the full rotationally invariant Kanamori interaction in order to ensure a correct description of atomic multiplets^{5}. To solve the DMFT quantum impurity problem, we used the strong-coupling continuous-time Monte Carlo impurity solver^{43} as implemented in the TRIQS library^{44}. In the *U* and *J* parameters of the Kanamori interaction, we used *U*=2.3 eV and *J*=0.4 eV, which successfully explains the correlated phenomena of other ruthenate such as Sr_{2}RuO_{4} and *A*RuO_{3} (*A*=Ca, Sr) within the DFT+DMFT framework^{27,28}.

### Data availability

All relevant data are available from the authors.

## Additional information

**How to cite this article:** Sutter, D. *et al*. Hallmarks of Hunds coupling in the Mott insulator Ca_{2}RuO_{4}. *Nat. Commun.* **8**:15176 doi: 10.1038/ncomms15176 (2017).

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## References

- 1.
Imada, M., Fujimori, A. & Tokura, Y. Metal-insulator transitions.

*Rev. Mod. Phys.***70**, 1039–1263 (1998). - 2.
Monceau, P. Electronic crystals: an experimental overview.

*Adv. Phys.***61**, 325–581 (2012). - 3.
Hashimoto, M., Vishik, I. M., He, R.-H., Devereaux, T. P. & Shen, Z.-X. Energy gaps in high-transition-temperature cuprate superconductors.

*Nat. Phys.***10**, 483–495 (2014). - 4.
Fradkin, E., Kivelson, S. A. & Tranquada, J. M. Colloquium: Theory of intertwined orders in high temperature superconductors.

*Rev. Mod. Phys.***87**, 457–482 (2015). - 5.
Georges, A., de’ Medici, L. & Mravlje, J. Strong correlations from Hund’s coupling.

*Annu. Rev. Condens. Matter Phys.***4**, 137–178 (2013). - 6.
Kunkemöller, S.

*et al.*Highly anisotropic magnon dispersion in Ca_{2}RuO_{4}: evidence for strong spin orbit coupling.*Phys. Rev. Lett.***115**, 247201 (2015). - 7.
Jain, A.

*et al.*Soft spin-amplitude uctuations in a Mott-insulating ruthenate http://arxiv.org/abs/1510.07011 (2015). - 8.
Khaliullin, G. Excitonic magnetism in Van Vleck type

*d*^{4}Mott insulators.*Phys. Rev. Lett.***111**, 197201 (2013). - 9.
Fatuzzo, C. G.

*et al.*Spin-orbit-induced orbital excitations in Sr_{2}RuO_{4}and Ca_{2}RuO_{4}: a resonant inelastic x-ray scattering study.*Phys. Rev. B***91**, 155104 (2015). - 10.
Damascelli, A.

*et al.*Fermi surface, surface states, and surface reconstruction in Sr_{2}RuO_{4}.*Phys. Rev. Lett.***85**, 5194–5197 (2000). - 11.
Zabolotnyy, V. B.

*et al.*Surface and bulk electronic structure of the unconventional superconductor Sr_{2}RuO_{4}: unusual splitting of the band.*New J. Phys.***14**, 063039 (2012). - 12.
Puchkov, A. V.

*et al.*Layered ruthenium oxides: from band metal to Mott insulator.*Phys. Rev. Lett.***81**, 2747–2750 (1998). - 13.
Mizokawa, T.

*et al.*Spin-orbit coupling in the Mott insulator Ca_{2}RuO_{4}.*Phys. Rev. Lett.***87**, 077202 (2001). - 14.
Nakatsuji, S.

*et al.*Mechanism of hopping transport in disordered Mott insulators.*Phys. Rev. Lett.***93**, 146401 (2004). - 15.
Neupane, M.

*et al.*Observation of a novel orbital selective Mott transition in Ca_{1.8}Sr_{0.2}RuO_{4}.*Phys. Rev. Lett.***103**, 097001 (2009). - 16.
Shimoyamada, A.

*et al.*Strong mass renormalization at a local momentum space in multiorbital Ca_{1.8}Sr_{0.2}RuO_{4}.*Phys. Rev. Lett.***102**, 086401 (2009). - 17.
Anisimov, V., Nekrasov, I., Kondakov, D., Rice, T. & Sigrist, M. Orbital-selective Mott-insulator transition in Ca

_{2−x}Sr_{x}RuO_{4}.*Eur. Phys. J. B***25**, 191 (2002). - 18.
Koga, A., Kawakami, N., Rice, T. M. & Sigrist, M. Orbital-selective Mott transitions in the degenerate Hubbard model.

*Phys. Rev. Lett.***92**, 216402 (2004). - 19.
Liebsch, A. & Ishida, H. Subband filling and Mott transition in Ca

_{2−x}Sr_{x}RuO_{4}.*Phys. Rev. Lett.***98**, 216403 (2007). - 20.
Gorelov, E.

*et al.*Nature of the Mott Transition in Ca_{2}RuO_{4}.*Phys. Rev. Lett.***104**, 226401 (2010). - 21.
Watanabe, H., Po, H. C., Vishwanath, A. & Zaletel, M. Filling constraints for spin-orbit coupled insulators in symmorphic and nonsymmorphic crystals.

*PNAS***112**, 14551–14556 (2015). - 22.
Park, K. T. Electronic structure calculations for layered LaSrMnO

_{4}and Ca_{2}RuO_{4}.*J. Phys. Condens. Matter***13**, 9231 (2001). - 23.
Liu, G.-Q. Spin-orbit coupling induced Mott transition in Ca

_{2−x}Sr_{x}RuO_{4}(0≤*x*≤0.2).*Phys. Rev. B***84**, 235136 (2011). - 24.
Acharya, S., Dey, D., Maitra, T. & Taraphder, A. The isoelectronic series Ca

_{2−x}Sr_{x}RuO_{4}: structural distortion, effective dimensionality, spin fluctuations and quantum criticality.*arXiv*:1605.05215 (2016). - 25.
Woods, L. M. Electronic structure of Ca

_{2}RuO_{4}: a comparison with the electronic structures of other ruthenates.*Phys. Rev. B***62**, 7833–7838 (2000). - 26.
Georges, A., Kotliar, G., Krauth, W. & Rozenberg, M. J. Dynamical mean-field theory of strongly correlated fermion systems and the limit of infinite dimensions.

*Rev. Mod. Phys.***68**, 13–125 (1996). - 27.
Mravlje, J.

*et al.*Coherence-incoherence crossover and the mass-renormalization puzzles in Sr_{2}RuO_{4}.*Phys. Rev. Lett.***106**, 096401 (2011). - 28.
Dang, H. T., Mravlje, J., Georges, A. & Millis, A. J. Electronic correlations, magnetism, and Hund’s rule coupling in the ruthenium perovskites SrRuO

_{3}and CaRuO_{3}.*Phys. Rev. B***91**, 195149 (2015). - 29.
Fukazawa, H., Nakatsuji, S. & Maeno, Y. Intrinsic properties of the Mott insulator Ca

_{2}RuO_{4+δ}.*Physica B***281**, 613–614 (2000). - 30.
Nakatsuji, S. & Maeno, Y. Synthesis and single-crystal growth of Ca

_{2−x}Sr_{x}RuO_{4}.*J. Solid State Chem.***156**, 26–31 (2001). - 31.
Blöchl, P. E. Projector augmented-wave method.

*Phys. Rev. B***50**, 17953–17979 (1994). - 32.
Kresse, G. & Joubert, D. From ultrasoft pseudopotentials to the projector augmented-wave method.

*Phys. Rev. B***59**, 1758–1775 (1999). - 33.
Kresse, G. & Hafner, J.

*Ab initio*molecular dynamics for open-shell transition metals.*Phys. Rev. B***48**, 13115–13118 (1993). - 34.
Kresse, G. & Furthmüller, J. Efficient iterative schemes for

*ab initio*total-energy calculations using a plane-wave basis set.*Phys. Rev. B***54**, 11169–11186 (1996). - 35.
Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized gradient approximation made simple.

*Phys. Rev. Lett.***77**, 3865–3868 (1996). - 36.
Marzari, N. & Vanderbilt, D. Maximally localized generalized Wannier functions for composite energy bands.

*Phys. Rev. B***56**, 12847–12865 (1997). - 37.
Souza, I., Marzari, N. & Vanderbilt, D. Maximally localized Wannier functions for entangled energy bands.

*Phys. Rev. B***65**, 035109 (2001). - 38.
Franchini, C.

*et al.*Maximally localized Wannier functions in LaMnO_{3}within PBE+ U, hybrid functionals and partially self-consistent GW: an efficient route to construct ab initio tight-binding parameters for*e*_{g}perovskites.*J. Phys. Condens. Matter***24**, 235602 (2012). - 39.
Aichhorn, M.

*et al.*Dynamical mean-field theory within an augmented plane-wave framework: assessing electronic correlations in the iron pnictide LaFeAsO.*Phys. Rev. B***80**, 085101 (2009). - 40.
Aichhorn, M.

*et al.*TRIQS/DFTTools: a TRIQS application for*ab initio*calculations of correlated materials.*Comput. Phys. Commun.***204**, 200–208 (2016). - 41.
Parcollet, A.

*et al.*TRIQS: a toolbox for research on interacting quantum systems.*Comput. Phys. Commun.***196**, 398–415 (2015). - 42.
Blaha, P., Schwarz, K., Madsen, G., Kvasnicka, D. & Luitz, J. WIEN2k: an augmented plane wave plus local orbitals program for calculating crystal properties.

*Technische Universität Wien*(2001). - 43.
Gull, E.

*et al.*Continuous-time Monte Carlo methods for quantum impurity models.*Rev. Mod. Phys.***83**, 349–404 (2011). - 44.
Seth, P., Krivenko, I., Ferrero, M. & Parcollet, O. TRIQS/CTHYB: a continuous-time quantum Monte Carlo hybridisation expansion solver for quantum impurity problems.

*Comput. Phys. Commun.***200**, 274–284 (2016).

## Acknowledgements

D.S., J.C., C.G.F. and H.M.R. acknowledge support by the Swiss National Science Foundation and its Sinergia network MPBH. Y.S. is supported by the Wenner-Gren foundation. T.-R.C. and H.-T.J. are supported by the Ministry of Science and Technology, National Tsing Hua University, National Cheng Kung University and Academia Sinica, Taiwan. T.-R.C. and H.-T.J. also thank NCHC, CINC-NTU and NCTS, Taiwan for technical support. A.G. and M.K. acknowledge the support of the European Research Council (ERC-319286 QMAC, ERC-617196 CORRELMAT) and the Swiss National Science Foundation (NCCR MARVEL). S.M. acknowledges support by the Swiss National Science Foundation (Grant No. P2ELP2-155357). This work was performed at the SIS, I05 and MAESTRO beamlines at the Swiss Light Source, Diamond Light Source and Advanced Light Source, respectively. We acknowledge Diamond Light Source for time on beamline I05 under proposal SI14617 and SI12926 and thank all the beamline staff for technical support. The Advanced Light Source is supported by the Director, Office of Science, Office of Basic Energy Sciences, of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231. M.K. and A.G. are grateful to M. Ferrero, O. Parcollet and P. Seth for discussions and support.

## Author information

## Author notes

- D. Sutter
- & C. G. Fatuzzo

These authors contributed equally to this work.

## Affiliations

### Physik-Institut, Universität Zürich, Winterthurerstrasse 190, Zürich CH-8057, Switzerland

- D. Sutter
- , F. Cossalter
- , T. Neupert
- & J. Chang

### Institute of Physics, École Polytechnique Fedérale de Lausanne (EPFL), Lausanne CH-1015, Switzerland

- C. G. Fatuzzo
- , G. Gatti
- , M. Grioni
- & H. M. Rønnow

### Advanced Light Source (ALS), Berkeley, California 94720, USA

- S. Moser
- , C. Jozwiak
- , A. Bostwick
- & E. Rotenberg

### College de France, Paris Cedex 05 75231, France

- M. Kim
- & A. Georges

### Centre de Physique Théorique, Ecole Polytechnique, CNRS, Univ Paris-Saclay, Palaiseau 91128, France

- M. Kim
- & A. Georges

### CNR-SPIN, Fisciano, Salerno I-84084, Italy

- R. Fittipaldi
- , A. Vecchione
- & V. Granata

### Dipartimento di Fisica ‘E.R. Caianiello’, Università di Salerno, Fisciano, Salerno I-84084, Italy

- R. Fittipaldi
- , A. Vecchione
- & V. Granata

### Department of Physics and Astronomy, Uppsala University, Uppsala S-75121, Sweden

- Y. Sassa

### Swiss Light Source, Paul Scherrer Institut, Villigen PSI CH-5232, Switzerland

- N. C. Plumb
- , C. E. Matt
- & M. Shi

### Diamond Light Source, Harwell Campus, Didcot OX11 0DE, UK

- M. Hoesch
- & T. K. Kim

### Department of Physics, National Tsing Hua University, Hsinchu 30013, Taiwan

- T-R Chang
- & H-T Jeng

### Department of Physics, National Cheng Kung University, Tainan 701, Taiwan

- T-R Chang

### Institute of Physics, Academia Sinica, Taipei 11529, Taiwan

- H-T Jeng

### Department of Quantum Matter Physics, University of Geneva, Geneva 4 1211, Switzerland

- A. Georges

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### Contributions

R.F., A.V. and V.G. grew and prepared the Ca_{2}RuO_{4} single crystals. D.S., C.G.F., M.S., F.C., Y.S., G.G., M.G., H.M.R., N.C.P., C.E.M., M.S., M.H., T.K.K. and J.C., prepared and carried out the ARPES experiment. D.S., C.G.F., F.C. and J.C. performed the data analysis. T.-R.C., H.-T.J. and T.N. made the DFT band structure calculations. M.K. and A.G. performed and analysed the DMFT calculations. All authors contributed to the manuscript.

### Competing interests

The authors declare no competing financial interests.

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