Abstract
One often counts the nearest neighbouring (NN) exchange interactions for understanding of a magnetic insulator. Here we present first-principles calculations for the newly synthesized double perovskites Sr2NiIrO6 and Sr2ZnIrO6 and we find that the 2NN Ir-Ir antiferromagnetic coupling is even stronger than the 1NN Ni-Ir ferromagnetic one. Thus, the leading antiferromagnetic interactions in the fcc Ir sublattice give rise to a magnetic frustration. Sr2NiIrO6 and Sr2ZnIrO6 hence appear very similarly as a distorted low-temperature antiferromagnet (probably, of type III). This work highlights the long-range magnetic interactions of the delocalized 5d electrons and it also addresses why the spin-orbit coupling is ineffective here.
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Introduction
In the insulating transition-metal (TM) oxides, superexchange (SE) coupling of neighbouring magnetic ions via intermediate oxygen, according to the Goodenough-Kanamori-Anderson rules1, commonly plays a leading role in their magnetic order. One simple but useful rule is that for a linear M-O-M′ exchange path, the SE would be antiferromagnetic (AF) [ferromagnetic (FM)] when the active orbitals of M and M′ are same [different]. Fig. 1 (a) shows two d1 ions each having two orthogonal A–B levels and the same A-level occupation. Taking into account an effective hopping t between two ions associated with the charge fluctuation (d1 + d1 → d0 + d2) where the electron correlation Hubbard U is involved, an energy gain of an AF order (relative to a FM one) is proportional to t2/U in a strong correlation limit (U ≫ t). Fig. 1 (b) shows two different d1 level occupations and a FM stability against AF is proportional to t2JH/U2 where JH is a Hund exchange. This is the reason why a FM Mott insulator is often associated with orbital physics (e.g., an orbital ordering) and its TC is much lower (due to the factor JH/U ~ 1/5) than the TN of many AF Mott insulators.
In practice, it is often sufficient to consider the SE between the nearest neighbouring (NN) magnetic ions only. This approach applies with much success to numerous insulating 3d TM oxides, where the 3d electrons are quite localized due to the strong correlation effect. In recent years, 5d TM oxides have received considerable attention due to their significant spin-orbit coupling (SOC) effect and possibly exotic properties2,3,4,5,6,7,8,9,10. The hybrid 3d–5d TM oxides are also of current great interest for exploration of novel magnetic and electronic properties in this material system, in which new SOC effects add to the common charge-spin-orbital physics appearing in the 3d TM oxides. Among them, the double perovskites A2BB′O6 (A = alkaline earth metal, B = 3d TM and B′ = 5d TM) are an important material platform11,12,13,14,15,16,17,18,19,20,21,22: Sr2FeReO6 is an above room temperature (RT) ferrimagnetic half metal11 and Sr2CrOsO4 is a ferrimagnetic insulator with a seemingly highest TC in the perovskite oxides13,14, etc. As 5d electrons are moderately or weakly correlated and their orbitals are much delocalized, their magnetic coupling could well be a long-range interaction.
In this work, we study the electronic structure and magnetism of the newly synthesized double perovskite Sr2NiIrO617, using density functional calculations. This material crystallizes in the monoclinic space group P21/n at RT (see Fig. 2) and undergoes two structural phase transitions (P21/n → I4/m → Fm-3m) upon heating. Magnetic susceptibility measurements17 suggest the establishment of AF interactions at TN = 58 K. This oxide has the Ni2+ (t62ge2g)-Ir6+ (t32g) charge state as seen below. Taking into account a charge fluctuation into the common Ni3+-Ir5+ state (a reverse Ni+-Ir7+ is quite unusual), both the Ni up-spin eg and down-spin t2g electron hopping (the Ni up-spin t2g levels lie lowest due to the crystal field splitting and Hund exchange) would give a FM SE between the Ni2+ and Ir6+ ions, see Figs. 1(c) and 1(d). As the eg and t2g levels are orthogonal, the eg (t2g) electron hopping follows the simple SE mechanism plotted in Fig. 1(b) [Fig. 1(a)]. Apparently, this expected FM order contradicts the observed AF in Sr2NiIrO6 and thus consideration of only NN Ni2+-Ir6+ coupling would be a mistake here. Then, a possibly long-ranged Ir-Ir coupling within the fcc sublattice should be invoked, which would be AF due to the half-filled t32g shells [Figs. 1(d) and 1(e)]. As we calculate below, there is indeed a long-range AF interaction in the fcc Ir6+ sublattice and the second NN Ir-Ir AF coupling energy is even bigger than the first NN Ni-Ir FM one, thus giving rise to a magnetic frustration23,24,25,26. As a result, Sr2NiIrO6 behaves as a distorted low-temperature antiferromagnet17 (probably, of type III)24,25,26. Naturally, the frustrated AF couplings in the fcc Ir6+ sublattice explain a very similar magnetic property in the isostructural Sr2ZnIrO617. Note that one could take care of long-range magnetic interaction of the delocalized 5d electrons.
Results
We first study the electronic structure of Sr2NiIrO6 and the Ni-Ir charge state. Fig. 3 shows the orbitally resolved density of states (DOS) calculated by LSDA for the FM state. The delocalized Ir 5d electrons have a strong covalency with the ligand oxygens, giving rise to a large bonding-antibonding splitting. The pdσ splitting of the Ir eg electrons is up to 9 eV and the pdπ splitting of the Ir t2g electrons is about 6 eV. The Ir 5d electrons have a t2g-eg crystal-field splitting of more than 3 eV. Besides the occupied bonding states (around −6 eV) ascribed to the lower-lying O 2p bands, only the up-spin Ir t2g state is occupied, giving a formal Ir6+ charge state with a t32g (S = 3/2) configuration. In contrast, the Ni 3d electrons are confined and have a smaller pdσ (pdπ) bonding-antibonding splitting of 4 eV (2 eV) and the t2g-eg crystal-field splitting of 1–1.5 eV. Only the down-spin Ni eg antibonding state is unoccupied, giving a formal Ni2+ charge state with the t62ge2g (S = 1) configuration. Therefore, Sr2NiIrO6 has the Ni2+-Ir6+ charge state. Its closed subshells and a finite electron correlation would certainly make Sr2NiIrO6 insulating. However, in the present LSDA calculation, the bandwidth of the Ir t2g electrons is slightly larger than the exchange splitting, making the Ir t2g bands of two spin directions somewhat overlapping at the Fermi level. As seen below, this metallic solution will turn into a Mott insulating one upon inclusion of the electron correlation.
We now include the static electron correlation by carrying out LSDA + U calculations. The insulating band structure is shown in Fig. 4. It has a small band gap of 0.3 eV within the Ir t2g bands due to the moderate electron correlation of the delocalized Ir 5d electrons. The Ni 3d bands have a gap of more than 2 eV due to the strong correlation. The electron correlation enhances electron localization and reduces band hybridization and further stabilizes the Ni2+-Ir6+ charge state. The Ni2+ (S = 1) ion has a spin moment of 1.76 μB (see Table 1), being close to its formal value of 2 μB. The Ir6+ (S = 3/2) ion has a smaller moment of 1.46 μB reduced by the strong covalency with the oxygen ligands. Note that we also test the Ni3+-Ir5+ state, using constrained LSDA + U calculations. We initialize the corresponding occupation number matrix and the orbital polarized potential and consider a possible J = 0 singlet state of the Ir5+ ion due to its strong SOC. After a full electronic relaxation, however, the self-consistent LSDA + U + SOC calculations converge also to the present Ni2+-Ir6+ state.
As both the Ni2+ and Ir6+ ions are magnetic and form their respective fcc sublattices, their magnetic interactions are of concern. Here we study different magnetic structures using LSDA+U calculations. The G-AF state of Sr2NiIrO6 (FM Ni2+ and Ir6+ sublattices being AF coupled) turns out to be less stable than the FM state by 89 meV/fu, see Table 1. As the FM and G-AF states differ in the exchange energy only by the 1NN Ni-Ir couplings, which are ±6JNi−Ir per formula unit. Then the average exchange energy parameter of the 1NN Ni-Ir pairs can be estimated to be JNi−Ir = −89/12 ≈ −7.4 meV. This FM Ni-Ir coupling is readily understood by a SE mechanism, see Fig. 1 and the Introduction. However, the observed AF interaction17 at TN = 58 K questions this description. Therefore, we are motivated to study the long-range magnetic interactions, particularly those associated with the delocalized Ir 5d electrons. To do so, we use two artificial systems with either Ir6+ or Ni2+ magnetic sublattice only, Sr2ZnIrO6 [i.e., Sr2Zn(Ni)IrO6 in Table 1] and La2NiSiO6 both in the Sr2NiIrO6 structure, to calculate the 2NN Ir6+-Ir6+ and Ni2+-Ni2+ exchange parameters (J′Ir−Ir and J′Ni−Ni with a reference to the 1NN JNi−Ir). This approach avoids choices of complicate magnetic structures in bigger supercells and allows to estimate the two parameters separately. For Sr2Zn(Ni)IrO6, the layered AF state (FM ab planes being AF alternate along the c axis, see also Fig. 2) is more stable than the FM state by 84 meV/fu, see Table 1. The layered AF and FM states differ in the exchange energy only by the 2NN Ir-Ir couplings (with a reference to the 1NN Ni-Ir ones), i.e., −2J′Ir−Ir vs 6J′Ir−Ir. Then the energy difference gives AF J′Ir−Ir = 84/8 = 10.5 meV. The corresponding energy difference of 19 meV/fu for La2NiSiO6 gives AF J′Ni−Ni = 19/8 ≈ 2.4 meV, see Table 1.
As the magnetic Ir6+ and Ni2+ ions have closed subshells, the SE interactions naturally explain the AF J′Ir−Ir and J′Ni−Ni. Note that the Ni2+ 3d electrons are confined but the Ir6+ 5d electrons are delocalized, it is therefore not surprising that J′Ir−Ir is about four times as big as J′Ni−Ni. However, it is a bit surprising that the 2NN AF J′Ir−Ir is even bigger than the 1NN FM JNi−Ir, thus giving rise to a magnetic frustration in Sr2NiIrO6. This vital role of the strong 2NN AF Ir-Ir coupling is also manifested in the real double perovskite Sr2ZnIrO6, see below.
Sr2ZnIrO6 has a very similar crystal structure and magnetic property to Sr2NiIrO6 and it has AF interactions at TN = 46 K17. We have also calculated different magnetic states of Sr2ZnIrO6 and find the 2NN AF J′Ir−Ir = 75/8 ≈ 9.4 meV (see Table 1), being close to J′Ir−Ir = 10.5 meV in Sr2NiIrO6. As the delocalized Ir 5d electrons produce a long-range magnetic interaction, we also estimate the 3NN AF J″Ir−Ir (the exchange path along the linear Ir-O-Ni-O-Ir bonds with the Ir-Ir distance of 7.8 Å) by calculating the bilayered AF state of Sr2ZnIrO6. The bilayered AF state has FM ab planes but AF alternation every bilayer along the c axis and it is more stable than the FM state by 42 meV/fu. The exchange energy per formula unit can be expressed as 6J′Ir−Ir + 3J″Ir−Ir for the FM state and 2J′Ir−Ir + J″ Ir−Ir for the bilayered AF state. Therefore, the AF J″Ir−Ir is estimated to be (42 − 4 × 9.4)/2 = 2.2 meV.
Discussion
As seen from the above results, apparently the Ir-Ir magnetic interactions are long-ranged and have a non-negligible strength even at a distance of about 8 Å. It is the long-range AF interactions of the Ir6+ sublattice which make Sr2ZnIrO6 magnetically frustrated. As both J′Ir−Ir = 9.4 meV and J″Ir−Ir = 2.2 meV (see Table 1) are AF and J″Ir−Ir/J′Ir−Ir < 1/2, Sr2ZnIrO6 is most probably a type-III antiferromagnet24,25,26. Moreover, while the strongest 2NN AF J′Ir−Ir overwhelms the 1NN FM JNi−Ir and also makes Sr2NiIrO6 magnetically frustrated, the FM JNi−Ir could lift (or at least, partially) the frustration and select one state out of the degenerate manifold of fcc AF. In a word, the long-range magnetic interactions and frustration would make the cubic double perovskites Sr2NiIrO6 and Sr2ZnIrO6 distorted and this would partially relieve the magnetic frustration and eventually stabilize them into a similar low-temperature antiferromagnet17 which is worth a further experimental study.
Finally, we check if the SOC is important or not in the present materials. Normally, SOC is important in heavy 5d TMs and particularly, iridates recently receive great interest2,3,4,5,6,7,8,9,10. Owing to a large crystal-field splitting, iridates are in a low-spin state with only the t2g occupation (e.g., in a cubic crystal field). Then the SOC splits the t2g triplet (with also 2-fold spin degeneracy) into the lower J = 3/2 quartet and the higher J = 1/2 doublet2,3. We have used this SOC basis set to project the Ir6+ t2g DOS of Sr2ZnIrO6 calculated by LDA + SOC, but we find that the J = 3/2 and the J = 1/2 states are completely mixed, see Fig. 5(a). Therefore, the J = 3/2 and the J = 1/2 states are not at all eigen orbitals in Sr2ZnIrO6 (and in Sr2NiIrO6 with the same fcc Ir6+ sublattice). This is because the delocalized Ir 5d electrons form, with the intersite electron hoppings in the fcc sublattice (the high coordination of twelve), a ‘broad’ band with its bandwidth being more than 1 eV. Then the SOC effect is ‘killed’. In contrast, if the Ir-Ir coordination number is reduced as in the low-dimensional iridates, the SOC effect would be manifested. To check this, we also calculate the artificial system Sr2GaIr0.5Si0.5O6 (in Sr2ZnIrO6 structure) with alternating GaIr and SiGa planes. The Ga3+, Ir6+ and Si4+ ions have well comparable ionic sizes and they make charge balanced and the Ir6+-Ir6+ ions only four-coordinated. In this case, the SOC splitting of about 0.5 eV between the J = 3/2 and the J = 1/2 states is well restored as seen in Fig. 5(b) and thus the J = 3/2 and the J = 1/2 states would serve as eigen orbitals in a good approximation8.
The above results show that in Sr2ZnIrO6 and Sr2NiIrO6, the delocalized Ir6+ 5d electrons have an insignificant SOC effect due to the band formation in the fcc sublattice. Moreover, the half-filled t32g subshell of the high-valence Ir6+ ion has an intrinsic exchange splitting of about 1 eV, see Fig. 3. Both the band effect and the exchange splitting are stronger than the SOC strength, making the SOC ineffective in Sr2NiIrO6 and Sr2ZnIrO6. Our LSDA + U + SOC test calculations indeed show that the Ir6+ ion has only a small orbital moment of 0.07 μB, being antiparallel to the spin moment of about 1.3 μB reduced from the formal S = 3/2. Therefore, both Sr2ZnIrO6 and Sr2NiIrO6 can be described as an Ir6+ S = 3/2 fcc frustrated system, although Sr2NiIrO6 itself has an appreciable Ni2+-Ir6+ FM coupling.
In summary, using density functional calculations, we find that the newly synthesized isostructural double perovskites Sr2NiIrO6 and Sr2ZnIrO6 are insulating and have the formal Ir6+ S = 3/2 fcc sublattice, in addition to the Ni2+ S = 1 sublattice in the former. The delocalized Ir 5d electrons produce long-range magnetic interactions and the 2NN Ir-Ir AF interaction turns out to be even stronger than the 1NN Ni-Ir FM interaction. Therefore, the leading AF interactions in the fcc Ir sublattice give rise to a magnetic frustration in both Sr2NiIrO6 and Sr2ZnIrO6. As a result, both the cubic compounds appear as a distorted low-temperature antiferromagnet (probably, of type III). Note that the band formation in the high-coordination fcc Ir sublattice and the exchange splitting of the high-valence Ir6+ ion both make the SOC ineffective and the long-range interactions of the delocalized 5d electrons (band formation and magnetic coupling) would be taken care of.
Methods
Our calculations were performed using the full-potential augmented plane waves plus local orbital method (WIEN2K code)27. We took the structure data of Sr2NiIrO6 measured by neutron diffraction at RT17. The muffin-tin sphere radii are chosen to be 2.8, 2.1 and 1.5 Bohr for Sr, Ni/Ir and O atoms, respectively. The cutoff energy of 16 Ry is used for plane wave expansion of interstitial wave functions and 6 × 6 × 4 k mesh for integration over the Brillouin zone, both of which ensure a sufficient numerical accuracy. SOC is included by the second-variational method with scalar relativistic wave functions. We employ the local spin density approximation plus Hubbard U (LSDA + U) method28 and use the typical values, U = 6 eV and JH = 0.9 eV (U = 2 eV and JH = 0.4 eV), to describe electron correlation of the Ni 3d (Ir 5d) electrons. The calculated Mott insulating state of Sr2NiIrO6 remains unchanged in a reasonable range of the U values (U = 4–8 eV for Ni 3d and U = 1–3 eV for Ir 5d) and the corresponding variation of 1–2 meV for the exchange energy parameters does not affect our discussion and conclusion about the frustrated magnetism.
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Acknowledgements
This work was supported by the NSF of China (Grant Nos. 11274070 and 11474059), MOE Grant No. 20120071110006 and ShuGuang Program of Shanghai (Grant No. 12SG06). X.O. was also supported by the Outstanding Doctoral Student Project of Fudan University.
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H.W. conceived the idea and designed the research. X.O. performed the calculations, with helps of Z.L., F.F. and H.W. H.W. and X.O. prepared the manuscript.
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Ou, X., Li, Z., Fan, F. et al. Long-range magnetic interaction and frustration in double perovskites Sr2NiIrO6 and Sr2ZnIrO6. Sci Rep 4, 7542 (2014). https://doi.org/10.1038/srep07542
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DOI: https://doi.org/10.1038/srep07542
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