Investigations of metastable Ca₂IrO₄ epitaxial thin-films: systematic comparison with Sr₂IrO₄ and Ba₂IrO₄

Abstract

We have synthesized thermodynamically metastable Ca₂IrO₄ thin-films on YAlO₃ (110) substrates by pulsed laser deposition. The epitaxial Ca₂IrO₄ thin-films are of K₂NiF₄-type tetragonal structure. Transport and optical spectroscopy measurements indicate that the electronic structure of the Ca₂IrO₄ thin-films is similar to that of J_eff = 1/2 spin-orbit-coupled Mott insulator Sr₂IrO₄ and Ba₂IrO₄, with the exception of an increased gap energy. The gap increase is to be expected in Ca₂IrO₄ due to its increased octahedral rotation and tilting, which results in enhanced electron-correlation, U/W. Our results suggest that the epitaxial stabilization growth of metastable-phase thin-films can be used effectively for investigating layered iridates and various complex-oxide systems.

Introduction

The spin-orbit assisted Mott state discovered in layered iridates, e.g. Sr₂IrO₄, provides a new platform to realize unconventional properties of condensed matter due to the unique coexistence of strong spin-orbit coupling and electron-correlation¹. Recent studies have revealed the possibilities of novel electronic and magnetic phases in iridates such as Weyl semimetals^2,3 and a potential high-T_c superconducting state with d-wave gap^4,5,6,7. However, the fundamental electronic structure of the layered iridate is still under debate; namely, the insulating gap may open due to antiferromagnetic ordering, i.e. Slater scheme^8,9, rather than electron-correlation, i.e. Mott picture. Moreover, it is a formidable task to unveil the physics of layered iridates since only Sr₂IrO₄ and Ba₂IrO₄ (refs 10, 11, 12, 13) phases are available for experimental characterizations to date.

In this article, we report the systematic changes of the structural, transport and optical properties of layered iridates by investigating meta-stable Ca₂IrO₄ epitaxial thin-films. Since the Ruddlesden-Popper (R-P) phase of Ca₂IrO₄ is not thermodynamically stable, its bulk crystals do not exist in nature. However, we have successfully synthesized the R-P phase Ca₂IrO₄ thin-films (Fig. 1(b)) from a polycrystalline hexagonal (P62m) Ca₂IrO₄ bulk crystal (Fig. 1(a)) using an epitaxial stabilization technique¹⁴. The smaller ionic size of Ca²⁺ compared to Sr²⁺ causes increased IrO₆ octahedral rotation and/or tilting, hence a reduced electronic band-width (W). Thus, investigating Ca₂IrO₄ in a comparative study with Sr₂IrO₄ and Ba₂IrO₄ provides a unique opportunity to explore the layered iridate system, as it allows for the enhancement of the electronic correlation effect (U/W).

Figure 1

Schematic diagram of epitaxial stabilization of tetragonal Ca₂IrO₄ epitaxial thin-film from (a) the bulk hexagonal phase of Ca₂IrO₄, i.e. a target used in the pulsed laser deposition, to (b) metastable R-P phase of Ca₂IrO₄ thin-film grown on a single crystal YAlO₃ (110) substrate. (c) Powder x-ray diffraction of our target material, which shows x-ray diffraction peaks from the hexagonal bulk phase of P62m and a couple of small CaO peaks. (d) X-ray 2θ-ω scan of an epitaxial Ca₂IrO₄ thin-film, where only the (00l)-diffraction peaks of Ca₂IrO₄ are visible. YAlO₃ (110) and (220) peaks are labeled with asterisk (*) symbols.

Methods

We have grown metastable Ca₂IrO₄ epitaxial thin-films with the K₂NiF₄–type crystal structure on YAlO₃ (110) substrates by using a custom-built pulsed laser deposition (PLD) system with in-situ spectroscopic monitoring techniques¹⁵. The laser ablation is performed on a polycrystalline hexagonal (P62m) Ca₂IrO₄ target. The powder x-ray diffraction of the target is presented in Fig. 1(c). The samples are grown under the growth conditions of 1.2 J/cm² laser fluence (KrF excimer, λ = 248 nm) and 700 °C substrate temperature. In order to avoid defects such as oxygen vacancies during the growth, we have used a laser beam imaging technique with reduced laser beam size in PLD to minimize the kinetic energy of the plume¹⁶. This technique is essential for the successful growth of Ca₂IrO₄ thin-films. A relative high oxygen partial pressure of 10 mTorr is also used to minimize oxygen vacancies. The structural properties of the epitaxial Ca₂IrO₄ thin-films are measured using x-ray diffractometry (Bruker D8 Advance system with Cu-Ka radiation). Transport properties are measured using a Physical Property Measurement System (Quantum Design) with conventional four-probe and Hall geometries. Optical transmission spectra (T(ω)) are taken at normal incidence using a Fourier-transform infrared spectrometer in the photon energy region of 0.2–0.6 eV and a grating-type spectrophotometer in the range of 0.5–7 eV, where the substrates are transparent. The absorption spectra are calculated using where t is the thin film thickness.

Results and Discussion

The metastable R-P phase of the Ca₂IrO₄ thin films is verified by x-ray diffraction and reciprocal space mapping scans, which indicate that the films are stabilized by the epitaxial strain of the substrates and are of high crystalline quality. Figure 1(d) shows the θ-2θ x-ray diffraction scan with the (00l) peaks of a Ca₂IrO₄ thin film. The full width at half maximum of the (0012)-reflection rocking curve scan is 0.04°, which clearly shows good crystallinity of the film (Fig. 2(b)). The thickness of the Ca₂IrO₄ thin films is ca. 6 nm. The crystal quality deteriorates considerably as we increase the thickness further, presumably due to its thermodynamically metastable nature. In x-ray reciprocal space mapping (Fig. 2(a)), the (1118) peak of the film is vertically aligned with the YAlO₃ substrate (332)-reflection, indicating Ca₂IrO₄ films are coherently strained to the substrates, i.e. [110]_film//[001]_substrate and [001]_film//[110]_substrate. The lattice parameters obtained from the x-ray diffraction scans show that both in-plane (a) and out-of-plane (c) lattice parameters of Ca₂IrO₄ films are smaller than those of Sr₂IrO₄ (ref. 17) and Ba₂IrO₄ (ref. 10) (Fig. 2(c)). At this moment, the local structural information of Ca₂IrO₄ films, such as octahedral rotation and tilting, is unknown and requires substantial microscopic characterizations that we plan to perform as a future study. However, by assuming the rigid Ir-O bond-length to be constant, which is a reasonable assumption, we conjecture the reduced lattice constants (from x-ray diffraction) imply that the Ir-O-Ir bond angle is reduced from 158° (Sr₂IrO₄) to ca. 140° (Ca₂IrO₄). The reduced bond angle implies a corresponding reduction in bandwidth (W), according to the relation between bandwidth (W) and the Ir-O-Ir bond angle (θ) described by¹⁸:

Figure 2

(a) Reciprocal space map near the YAlO₃ (332)-reflection, which shows the Ca₂IrO₄ (1118)-reflection. The vertical dashed line indicates that the Ca₂IrO₄ thin-film is coherently strained to the substrate. (b) The rocking curve scan of Ca₂IrO₄ (0012)-reflection has a full-width half-maximum of 0.04°. (c) The in-plane (left axis) and out of plane (right axis) lattice parameters of Ca₂IrO₄, Sr₂IrO₄ (ref. 17) and Ba₂IrO₄ (ref. 10) thin films obtained from x-ray diffraction scans, as a function of A-site cation ionic radius. The solid circles and squares present the in-plane and out of plane lattice parameters, respectively. The open symbols indicate the in-plane and out of plane lattice parameters of Sr₂IrO₄ and Ba₂IrO₄ single crystals^12,23,24.

where d_Ir-O is the Ir-O bond length. This will result in an enhanced electron-correlation (U/W) for the Ca₂IrO₄ compound as compared to that of the Sr₂IrO₄ and Ba₂IrO₄ thin films.

Figure 3(a) shows the temperature-dependent resistivity ρ(T) of a Ca₂IrO₄ thin film, which has an insulating behavior. The room-temperature resistivity of Ca₂IrO₄ (ca. 170 mΩcm) is about the same as the room temperature resistivity of Sr₂IrO₄ (ca. 140 mΩcm) and Ba₂IrO₄ (ca. 130 mΩcm) deposited on SrTiO₃ substrates. The energy gap (Δ = 2E_a) of Ca₂IrO₄ is calculated using an Arrhenius plot (, where k_B is the Boltzmann constant) and compared to Sr₂IrO₄ (ref. 10) and Ba₂IrO₄ thin films. While the Arrhenius plots of Sr₂IrO₄ (ref. 10) and Ba₂IrO₄ show non-linear behaviors, the transport of Ca₂IrO₄ is quite linear over the entire measured temperature range (300 K to 90 K). An energy gap of 120 meV is extracted from its Arrhenius plot. Due to the increased U/W in Ca₂IrO₄, we expect its gap energy to be larger than that of Ba₂IrO₄ and Sr₂IrO₄. However, the energy gap of Ca₂IrO₄ obtained from the room temperature transport is smaller than that of Sr₂IrO₄ and Ba₂IrO₄. This puzzling observation implies that the transport properties of layered iridates are mostly dominated by impurities or defects and intrinsic bandgap energies should be measured using a spectroscopic technique.

Figure 3

(a) Normalized resistivity (ρ) versus temperature data of Ca₂IrO₄ (red), Sr₂IrO₄ (blue) and Ba₂IrO₄ (green) thin-films. The data of Sr₂IrO₄ is from ref. 10; The inset shows the Arrhenius plot of Ca₂IrO₄, Sr₂IrO₄ and Ba₂IrO₄. Solid black lines present the linear fits at room temperature and low temperature. The estimated gap energies at room temperature are Δ_CIO = 120 meV, Δ_SIO = 250 meV and Δ_BIO = 190 meV. The Arrhenius plots are shifted vertically for clarity. (b) Optical absorption spectra (α (ω)) of Ca₂IrO₄, Sr₂IrO₄ and Ba₂IrO₄ thin-films at room temperature. The plots are shifted vertically by 10⁵ cm^−1 for clarity. The α, β and γ represent the optical transition peak energies obtained from the fit with the minimal set of the Lorentz oscillators. The solid black curves are the fit curves using Lorentz oscillators, which match well with the experimental spectra. (c) Fitted absorption spectra of Ca₂IrO₄, Sr₂IrO₄ and Ba₂IrO₄ at low energy using Wood-Tauc’s method²¹ which clearly confirm the increased energy gap from Ba₂IrO₄ to Ca₂IrO₄. The estimated optical gap energies using this method are Δ_CIO = 210 meV, Δ_SIO = 150 meV and Δ_BIO = 110 meV.

Figure 3(b) presents the optical absorption spectra (α(ω)) of Ca₂IrO₄ compared with Sr₂IrO₄ (ref. 17) and Ba₂IrO₄ (ref. 10) thin films. The absorption spectra are fit using a minimal set of Lorentz oscillators. The common features of strong absorption tails due to the charge-transfer transitions from O 2p to Ir 5d bands are above ca. 2–3 eV. The black solid lines in Fig. 3(b) are the resultant fit curves using Lorentz oscillators, which match well with the experimental spectra. The three absorption peaks indicated by α, β and γ are labeled consistently with previous literature^19,20. The α, β and γ absorption bands have been interpreted as the associated Ir 5d transitions, such as Ir-Ir intersite optical transitions^1,19,20. Note that as the cation size — and consequently the Ir 5d bandwidth — increases from Ca₂IrO₄ to Ba₂IrO₄, the α, β and γ peak-positions are shifted to higher energy. This seemingly counterintuitive peak shift has also been observed in the optical absorption spectra of strain-dependent Sr₂IrO₄ thin-films¹⁷, as the lattice strain changes from compressive to tensile directions. This observation of the peak-energy shift can provide a key to understanding the electronic structures of iridates since the spectral shape is thought to be strong experimental evidence supporting the Mott picture of this system^1,19,20. However, we will leave it as a future study since detailed analysis requires theoretical modeling and calculations, which is beyond the scope of this article.

We note the increased optical gap energy of Ca₂IrO₄ thin-films as compared to that of Sr₂IrO₄ and Ba₂IrO₄. To calculate the optical energy gap, each absorption spectrum is fit using the Wood-Tauc’s method²¹ (Fig. 3(c)). In this method, the strong region of the absorption edge (α > 10⁴ cm^−1) can be described by:

where E_g (E) is the optical band gap (incident photon) energy. The estimated optical gap energies using this method are Δ_CIO = 210 meV, Δ_SIO = 150 meV and Δ_BIO = 110 meV. For the exponent γ, we have obtained γ = 1.5 (Ca₂IrO₄), γ = 3.0 (Sr₂IrO₄) and γ = 1.5 (Ba₂IrO₄). While γ = 3 is consistent with the indirect bandgap of Sr₂IrO₄, γ = 1.5 values in Ca₂IrO₄ and Ba₂IrO₄ suggests direct bandgap, of which physical understanding will require further theoretical studies. Nevertheless, as shown in Fig. 3(c), the optical gap energy has clearly increased for Ca₂IrO₄ compared to that of Sr₂IrO₄ and Ba₂IrO₄. Hence, as we decrease the ionic sizes of A-site cations in layered iridates, the Ir-O-Ir bond angle is reduced, which, in turn, increases U/W and manifests itself as the observed increase in the optical bandgap energy.

Our approach of synthesizing meta-stable phase thin-films of strongly correlated systems offers a new route to understanding the physics of complex oxides. For example, the stabilization of metastable phases can provide compounds with larger effective electronic correlations than presently available by producing increased distortion and tilting in lattice. While simple octahedral distortions usually preserve inversion symmetry in the K₂NiF₄–type structure, the R-P structure of Ca₂IrO₄ has been proposed as a candidate material featuring a non-centrosymmetric structure due to its low symmetry²². This unique structure, achieved by breaking the inversion symmetry in this system, is expected to induce many interesting phase transitions such as ferroelectricity and multiferroicity. Hence, experimental studies of meta-stable phases allow us to tackle a number of intriguing problems of exotic ground states with novel properties that are theoretically suggested.

Conclusion

We have successfully stabilized Ca₂IrO₄ thin-films with the K₂NiF₄–type crystal structure and determined its higher optical gap energy to originate from its enhanced electron-correlation, U/W, with respect to its larger A-site cation isosymmetric compounds. The structural study confirms the good crystallinity and coherent strain state of the epitaxial Ca₂IrO₄ thin-films on YAlO₃ (110) substrates. The transport and optical spectroscopic experiments show that Ca₂IrO₄ thin-films have an insulating ground state similar to Sr₂IrO₄ and Ba₂IrO₄. However, the increased IrO₆ octahedral rotation, tilting, or distortion in Ca₂IrO₄ increases U/W and thus its optical gap energy is larger than the gap energies of Sr₂IrO₄ and Ba₂IrO₄. This approach of metastable thin-film phases can greatly expand the number of available materials and can help to unveil the physics of strongly correlated systems.