A hybrid-exchange density-functional theory study of the electronic structure of MnV O : Exotic orbital ordering in the cubic structure 2 4 ∗ Wei Wu Department of Electronic and Electrical Engineering and London Centre for Nanotechnology, University College London, Gower Street, London, WC1E 6BT, United Kingdom TheelectronicstructuresofthecubicandtetragonalMnV2O4 havebeenstudiedbyusinghybrid- exchangedensityfunctionaltheory. Thecomputedelectronicstructureofthetetragonalphaseshows ananti-ferroorbitalorderingonVsitesandaferrimagneticgroundstate(thespinsonVandMnare 5 anti-aligned). These results are in a good agreement with the previous theoretical result obtained 1 from the local-density approximation+U methods [S. Sarkar, et. al., Phys. Rev. Lett. 102, 216405 0 (2009)]. Moreover, the electronic structure, especially the projected density of states of the cubic 2 phasehasbeenpredictedwithagoodagreementwiththerecentsoftx-rayspectroscopyexperiment. r Similartothetetragonalphase,thespinsonVandMninthecubicstructurefavouraferrimagnetic p configuration. Most interesting is that the computed charge densities of the spin-carrying orbitals A onVinthecubicphaseshowanexoticorbitalordering,i.e.,aferro-orbitalorderingalong[110]but an anti-ferro-orbital ordering along [110]. 3 1 PACSnumbers: 71.15.Mb,75.47.Lx,75.50.Gg,75.25.Dk ] l e I. INTRODUCTION be thought of as a prototype of TMO-based metamate- - r rials or even quantum metamaterials [11, 14]. Another t s unique point for vanadium spinels is that they are t2g- t. Many fascinating phenomena in condensed-matter active, in sharp contrast to most of the known TMOs a physics were discovered in transition-metal oxides showing OO. In this type of compound, the V3+ ions on m (TMOs) and their closely related compounds such as theBsitesformapyrochlorelattice. Thetwod-electrons d- the first high transition temperature superconductivity on V occupying two t2g orbitals lead to a total spin of n inYBaCuO3 [1,2]. Animportantorderingphenomenon, S =1, resulting in a t2g-activeOO.The OO in this type o Orbital ordering (OO) has a long history in the physics of compounds is further complicated by their intrinsic c of TMOs, back to the 1930s,when the conceptof charge geometrical frustration, which played an important role [ orderinginFe3O4 wasproposed[3]. OOoccurswhenthe in OO. In 1939, the charge ordering on the B-site py- orbital degeneracy is lifted essentially by the interaction rochlore lattice was proposed to cause a sharp increase 4 v with the lattice environment [4, 5]. The best-known ex- of the electrical resistivity when cooling below ∼ 120 K 2 ample of OO is the Jahn-Teller (JT) distortion observed in Fe3O4 (the ’Verwey’ transition) [3]. Anderson was 2 in LaMnO3 [6]. Thereinthe eg degenerate manifold (dz2 the first to realise the intimate relationship between the 3 anddx2−y2)ina cubicenvironmentisfurther splittedby proton ordering in the ice, the Verwey charge ordering, 0 the JT distortion owing to partially filling of electrons. and the ordering of Ising spins [15]. Regardless of the 0 The underlying physics in OO has been well accounted specific material types, geometrical frustration plays a . 1 for by the so-called Kugel-Khomskiimodel [7]. Most ex- crucial role to determine the spin or charge configura- 0 perimental and theoretical works so far have been fo- tions,byminimisingexchangeorCoulombenergies. This 5 cused on the system with partially filled eg orbitals, i.e., will in turn trigger many interesting phenomena such as 1 : eg active. This type of orbital occupancy can lead to orbital-glass and orbital-ice states [16–18]. In addition, v the strongest JT effect because the related d-orbitals di- themuchfasterresponseofelectronchargesascompared Xi rectly point to ligands and strongly hybridise with the to electronspins will find many potential applications in 2p-orbitals of the anion. advanced electronics such as orbitronics [19]. r a Recently much attention has been paid to vanadium spinels AB2O4 (A = Mg, Co, Fe, Mn, and Cd, etc and MnV2O4 (See Fig.1), in which the Mn2+ ion is in a d5 B=V) [8–13]owingtotheir fascinatingspinandorbital half-filled high-spin configuration (S = 5), first experi- 2 orderingsaccompaniedbycomplexstructuraltransitions encesamagnetictransitiontothecollinearferrimagnetic atlowtemperature. Theinterplaybetweenstructure,or- state at T = 56 K, and then a structural distortion at a bital, and spin implies that the underlying physics could slightly lower temperature T =53 K, along with a tran- beveryinteresting,andthattheremightbelargeapplica- sition to the non-collinear ferrimagnetic state [20, 21]. tionpotentialinthesematerials. Forexample,artificially Theobservedmagnetic orderingbelowT =56K isferri- tuning structure by applying externalmagnetic field can magnetic, i.e., the magnetic moments on Mn2+ and V3+ are anti-aligned. In the structural transition, the sym- metry is lowered from cubic to tetragonal. The OO of the ground state in the tetragonal MnV2O4 structure ∗Electronicaddress: [email protected] hasbeen showntheoretically[12]as anA-type antiferro- 2 orbital ordering with a propagationvector of (002). ing DFT and hybrid-exchange functional PBE0 as im- plemented in the CRYSTAL 09 code [29]. The crystal structuresofthe cubic (spacegroupFd3m)andtetrago- nal (space group I41/amd) MnV2O4 experimentally de- termined in Ref.[11] have been adopted here to perform all the calculations. The basis sets for the atomic or- bitals centred on the Mn[30], V[31], and O[32] atoms, whicharedesignedforsolid-statecompounds,wereused. The Monkhorst-Pack samplings [33] of reciprocal space were carried out choosing a grid of shrinking factor to be 6 × 6 × 6 (6 × 6 × 5) in order for a consistency with the ratios among reciprocal lattice parameters for the cubic (tetragonal) MnV2O4. The truncation of the Coulomb and exchange series in direct space was con- trolled by setting the Gaussian overlap tolerance crite- ria to 10−6,10−6,10−6,10−6, and 10−12 [29]. The self- consistent field (SCF) procedure was convergedto a tol- erance of 10−6 a.u. per unit cell (p.u.c). To accelerate FIG. 1: (Color online.) the conventional cells in the cubic (left) and tetragonal (right) MnV2O4 crystal structures are convergenceoftheSCFprocess,allthe calculationshave shown. Mn is depicted as small yellow ball, V as large green beenconvergedbyusingalinearmixingofFockmatrices ball, and O as large red ball. by 30%. Electronic exchange and correlation are described us- Previously,theelectronicstructureandmagneticprop- ing the PBE0 hybrid functional [25], free of any empir- erties of the tetragonal MnV2O4 have been investigated ical or adjustable parameter. The advantages of PBE0 theoreticallyusingLDA(local-densityapproximation)+ include a partial elimination of the self-interaction er- U method[12],whereanorbitalorderingamongV3+ was ror and balancing the tendencies to delocalize and lo- proposed, along with a non-collinear magnetic ordering. calize wave-functions by mixing a quarter of Fock ex- Following this first-principles calculation, an analytical change with that from a generalized gradient approxi- modelling [22] has further confirmed that an antiferro- mation (GGA) exchange functional [25]. The broken- orbital ordering exists in the tetragonal MnV2O4. On symmetry method [34] is used to localize collinear op- the other hand, the electronic structure (especially OO) posite electron spins on atoms in order to describe the and magnetic properties of the cubic MnV2O4 are yet anti-ferromagnetic state. to be studied in detail. It might be worthwhile to (i) employ a computational method without any adjustable parameters,(ii)takeintoaccounttheelectroncorrelation III. RESULTS AND DISCUSSIONS properlyand(iii)comparetheelectronicstructuresofthe cubic and tetragonal MnV2O4. Hybrid-exchange func- A. Projected densities of states tionaltheory(HDFT),inwhichtheexactexchangeishy- bridisedwithgeneralisedgradientapproximation(GGA) The projected densities of states (PDOS) of the cubic functionaltolocalised-electrons,hasperformedwellfora and tetragonal MnV2O4 structures for the AFM config- wide range of inorganic and organic compounds [23, 24]. uration (the spins on Mn and V are anti-ligned) have Inthispaper,HDFTwithPBE0functional[25]hasbeen beenshowninFig.2. Thezeroenergyisalignedwiththe usedtostudytheelectronicstructureandmagneticprop- valence band maximum (VBM). erties of the cubic and tetragonal MnV2O4. The results In the cubic and tetragonal structures, Mn 3d PDOS presentedherearenotonlyinagoodagreementwiththe (Fig.2a and b) shows that the five d-orbitals including previoustheoreticalandrecentexperimentalstudies,but dx2−y2, dz2, dxz, dyz, and dxy are singly occupied, thus alsopointtoanexoticOOstatethatmixesferro-orbital- giving a spin-5. From the analysis of Mulliken spin den- and anti-ferro-orbital orderings. The rest of the discus- 2 sities and V 3d PDOS (Fig.2c and d), the two electrons sion is organised as the following: in §II computational occupyingt2g statescanbe identifiedasthe originofthe details are introduced, in §III the calculation results are OObothinthecubicandtetragonalMnV2O4. Inthecu- presented and discussed, and in §IV some general con- bic phase, the molecular orbitals delocalized among the clusions are drawn. three t2g states are occupied, whereas in the tetragonal phase, only d and d are involved. The O 2p PDOS xz yz (Fig.2e) for the cubic phase are much more delocalized II. COMPUTATIONAL DETAILS than those for the tetragonal(Fig.2f); this might be due to the elongation of the lattice vector a and b in the The calculations of the electronic structures of the tetragonal structure. The O 2p PDOS are particularly tetragonal and cubic MnV2O4 were carried out by us- dominant at ∼ 5 eV below the VBM for both the cubic 3 Cubic Tetragonal Cubic MnV2O4 AFM Mn-3d-orbital PDOS Tetragonal MnV2O4 AFM Mn-3d-orbital PDOS Density of states (states/eV/cell)-11-050500000 dddddxzxyx2zzy2-y2 Density of states (states/eV/cell)-22000 dddddxzxyx22zzy-y2 -10 -5 0 5 10 -10 -5 0 5 10 Energy (eV) Energy (eV) (a) (b) Cubic MnVO AFM V-3d-orbital PDOS Tetragonal MnVO AFM V-3d-orbital PDOS 2 4 2 4 of states (states/eV/cell)115050000 dddddxzxyx2zzy2-y2 of states (states/eV/cell)12468000000 dddddxzxyx2zzy2-y2 y y 0 Densit-50 Densit-20 -10 -5 0 5 10 -10 -5 0 5 10 Energy (eV) Energy (eV) (c) (d) Cubic MnVO AFM O-2p-orbital PDOS Tetragonal MnVO O-2p AFM PDOS 2 4 2 4 of states (states/eV/cell)500 222pppxyz of states (states/eV/cell)100 222pppxyz y y nsit-50 nsit-10 De De -10 -5 0 5 10 -10 -5 0 5 10 Energy (eV) Energy (eV) (e) (f) Cubic MnVO AFM PDOS Tetragonal MnVO AFM PDOS 2 4 2 4 V/cell)300 MV n3 d3d V/cell)200 MV-n3-d3d y of states (states/e-1120000000 O 2p y of states (states/e1000 O-2p Densit-200 Densit -10 -5 0 5 10 -100-10 -5 0 5 10 Energy (eV) Energy (eV) (g) (h) FIG.2: (Coloronline.) ThePDOSofthe3d-orbitalsonMn,the3d-orbitalsonV,andthe2p-orbitalsonOofthecubic(left) and tetragonal (right) MnV2O4 are shown. The PDOS onto dx2−y2 is in green, dz2 in red, dxz in blue, dyz in purple, and dxy in black, respectively. For 2p-orbitals, the PDOS onto 2px is in green, 2py in red, and 2pz in black, respectively. In (g) and (h),the total PDOS onto Mn d-orbitals is in red,V d-orbitals in green, and O 2p-orbitals in black, respectively. 4 and tetragonalstructures, which overlapwith the rather theotherhand,theexchangeinteractionbetweentheMn weakMn3dandV3dPDOS.TheO2porbitalsinvolved and V spins can also be estimated by using the super- here will give rise to the so-calledoxygenbonding states exchange formalism, where t can be quantified in the that feature the hybridisation between the d-orbitals on PDOS, which is ∼ 0.5 eV for Mn and ∼ 1 eV for V. By transitionmetalsandp-orbitalsonOatoms. Inaddition, using these hopping integrals, the exchange interaction it can be observed by comparing the spin-up and spin- can be estimated as tMntV (U = UMn+UV), which is ∼59 U 2 down PDOS, that the O 2p states have been strongly meV. This is in the same order as that calculated from spin-polarized by the magnetic moments on Mn and V. the total energy differences aforementioned (here an av- The PDOS onto the V sites have also been compared erage value is taken for on-site Coulomb interaction). A with the previous results obtained by the LDA+U [12], detailed discussion about the exchange interaction, tak- which suggests that there is a qualitative agreement be- ing into account all the d-orbitals on both Mn and V tween them except that the DFT band-gap computed would be great, but beyond the scope of this paper. here (∼ 3 eV) is larger than the previously computed one (∼ 1.1 eV) [12] and the observed (∼ 1.1 eV)[36]. The computed O 2p PDOS are in good agreement with C. Orbital ordering the intensities measured in the recent K-edge x-ray ab- sorption and emission spectra; the combination of the The OO in the cubic and tetragonal MnV2O4 can be theoretical work and experiments will be published in a illustratedbythespindensitiesonV(seeFig.3)–thedif- forthcoming paper [37]. ferencebetweenthe chargedensities ofspin-upandspin- Thecomputedcrystal-fieldsplittingbetweent2gandeg downorbitals(essentiallythechargedensitiesofthespin- statesofMn2+andV3+inthecubicMnV2O4canberead carry orbitals). In the tetragonal structure, the relative from Fig.2a, which is ∼1 eV. On the other hand, in the orientationrotationofneighbouringorbitalsisillustrated tetragonalMnV2O4,forbothMn2+ andV3+,dx2−y2 and by the red arrows in Fig.3b; this is consistent with the d are closely aligned while the other three 3d-orbitals xy previous calculations presented in Ref.[12] in which an overlap well, as shown in Fig.2b. This picture is consis- anti-ferro-orbital ordering (AFOO) has been predicted. tent with the previous calculations reported in Ref.[12]. The orbital orientations for the nearest-neighbouring The crystal-field splitting between these two groups is (NN) orbitals are perpendicular to each other (defined ∼ 1 eV. The on-site Coulomb interaction U can be ap- as AFOO).Insharpcontrast,forthe cubic structure the proximatedbyobservingthegapbetweenlowerHubbard NN orbtibals (labeled by X and Y in Fig.3a) are orga- d-bands and uppers ones (∼ 5 eV for Mn site, and ∼ 7 nized in an exotic way, in which the orbitals on one of eV for V), which is much larger than the crystal-field the four symmetry-inequivalent V atoms in the unit cell splitting computed here. This will result in a high-spin hasadifferentorbitalorientation(labeledbyY),perpen- state for Mn2+ and V3+ ions, which is consistent with dicular to the others (labeled by X). The orbital orien- the previous experiments [11]. tations corresponding to Fig.3a are further illustrated in Fig.3d, e,andf,whicharethe viewsofthe spindensities from the lattice direction [100] (~a), [010] (~b), and [001] B. Exchange interactions (~c), respectively. This leads to an exotic OO: a ferro- OO (FOO)along[110](blue arrowin Fig.3), whereasan The magnetic structure could be much more compli- AFOO along [110] (red arrow in Fig.3). This OO can cated owing to the exchange interaction between the probably be attributed to (i) the crystal field environ- nearest-neighbouring Mn (V) atoms [13] and the spin- ment formed by neighbouring oxygen atoms and (ii) the orbit coupling (SOC), which will cause the non-collinear Coulombinteractionbetweend-orbitals. Thisinteresting magnetic ordering. However, this topic is beyond the OOhasbeenfurtherconfirmedbythecalculationswitha scope of this paper that is focused on the electronic differenttypeofexchange-correlationfunctional,B3LYP structure and the collinear magnetic ground state. The [35], which relies on the empirical parameters for mixing Mulliken spin densities on the Mn and V sites for exactexchange and GGA exchangefunctional. The spin the cubic (tetragonal) MnV2O4 are 4.8 (4.7)µB and densities on V predicted by using B3LYP functional are −2.0 (−1.9)µ , respectively. They are close to the ex- showninFig.3c,inwhichFOOisalong[110]andAFOO B pected values, i.e. 5µ for Mn and −2µ for V (anti- [110] (all the atoms are made partially transparent in B B aligned). For the cubic (tetragonal) structure, the com- order to illustrate OO). putedtotalenergiesforaconventionalcellwiththespins To see the orbitals involved in the OO of the cubic on Mn and V aligned (ferromagnetic) is higher than the MnV2O4moreclearly,theatomicorbitalcompositionsof anti-aligned(AFM)by937(754)meV.Thisinturngives thebands(seeFig.4)attheΓ-pointthatcontributemost an approximate exchange interaction of ∼ 38 meV (di- tothetwopeaksat−0.26eVand−0.64eVintheVspin- vided by the factor of 4×SMn×SV=20, where 4 is the down PDOS (see Fig.2c) have been investigated. The number of Mn-V pairs in the unit cell for the tetragonal bandsVB−8andVB−9contributethe mosttothepeak structure). Similarly we can estimate the exchange in- at −0.26 eV, whereas VB−19 and VB−20 to the one at teractionforthe cubic structure,whichis ∼23meV. On −0.64eV.Althoughthe atomiccoefficientsford-orbitals 5 FIG. 3: (Colour on line.) The spin densities on V of the AFM state in the conventional unit cell of the cubic (a) and tetragonal (b) structures of MnV2O4 are shown. In the tetragonal an anti-ferro-orbital ordering is found. In contrast, in the cubicstructure,therotationoftheorbitalorientationillustratesanexoticOO,inwhichanferro-orbitalorderingisalong[110], while anti-ferro-orbital ordering along [110]. This exotic OO is further confirmed by the calculation from B3LYP functional; the resulting spin densities are shown in (c). The B3LYP spin-density calculation is performed in a unit cell, but shown in a conventional cell. The views from [100] (~a), [010] (~b), [001] (~c) lattice directions are shown in (d), (e), and (f), respectively. The isovalue is chosen as 0.04e/˚A3. are slightly different among V atoms, approximately the mostdominantlinearcombinationsofd-orbitalsforeach V atoms contained in these bands read, φVB−8 =0.2|dxzi+0.1|dyzi+0.2|dxyi, (1) φVB−9 =−0.1|dxzi+0.2|dyzi−0.2|dxyi, (2) φVB−19 =0.2|dxzi−0.1|dyzi−0.2|dxyi, (3) φVB−20 =0.2|dxzi+0.2|dyzi+0.1|dxyi. (4) The corresponding spherical harmonic functions have been plotted in Fig.5 to see the contributions of d- orbitals. From the perspectives of linear combination of atomic orbitals (LCAO), the strong variations of the orbital orientation illustrated in Fig.3 and Fig.5, result from the minimisation of the total energy respective to atomic orbital coefficients. On the other hand, the pro- cess of energy-minisation can be seen as the orbital re- orientation driven by Coulomb and crystal-field interac- tions. There are two concepts that are closely related to this exotic orbital ordering, including orbital glass and ice states. Theorbitalglassstateisformedbytherandomly orientatedorbitals,whichresultfromJahn-Tellerdistor- tion and orbital frustrations in a similar manner to spin frustrations [16, 17]. In light that orbital glass states have been observed in the spinel compounds FeCr2S4 and LuFe2O4 [16, 17] (which has similar chemical for- mula to a spinel, but a different structure), this is not FIG. 4: (Colour on line.) The spin-down band structure completely unexpectable in the cubic MnV2O4. There- (from -0.8 to 0 eV) of the AFM configuration in the cubic fore, these calculations could suggest that at T = 53 MnV2O4 is shown. Note that the two red arrows refer to K, there is not only a structural transition, but also an VB-8 and VB-9, and VB-19 and VB-20, respectively. orbital-orderingtransitionfromtheexoticOOillustrated 6 (a) (b) (c) (d) FIG.5: (Colouronline.) Thelinearcombinationofharmonicsphericalfunctionsareshown. 2Yxz+Yyz+2Yxy (corresponding toeq.(1))areshownin(a),−Yxz+2Yyz−2Yxy (correspondingtoeq.(2))in(b),2Yxz−Yyz−2Yxy (correspondingtoeq.(3))in (c), and 2Yxz+2Yyz+Yxy (corresponding to eq.(4)) in (d). Notice that the linear combination illustrated in (c) changes the orientation of orbitals significantly away from their original ones, which is closely related to theexotic OO shown in Fig.3a. inFig.3toanti-ferroorbitalordering[12], whenlowering todifferentelectrontransportproperties. Moreadvanced temperature. In addition, Chern and the collaborators theoreticalmethodssuchasdynamicalmean-fieldtheory have presented an ice model consisting of triplet orbital [38] is also needed to further understand the electronic variables (such as p-orbitals), which is however closely structure of MnV2O4. In the ground state the spins on related to orbital-drivenmany-body phenomena in opti- Mn and V are predicted to be anti-aligned, suggesting a cal lattice [18]. The analogue of spin-interacting Hamil- ferrimagnetic state for both structures, which is in good tonian, an orbital-exchange model describing Coulomb agreementwithprevioustheoreticalandexperimentalre- interactions has been used therein. The exotic ordering sults. The lower and upper Hubbard bands of Mn and presented here is closely related to the newly proposed V d-electrons have been shown clearly below and above concept of the orbital ice [18], similar to the spin ice. the band gap. The on-site Coulomb interaction can be estimatedby using the gapbetween the lowerandupper Hubbard bands, which is ∼ 7 eV for V and ∼ 5 eV for IV. CONCLUSION Mn, respectively. The transfer integral responsible for the delocalization is in the order of 1 eV, which should The electronic structures of the cubic and tetrago- be attributed to a combination of the first-order direct nal MnV2O4 structures have been computed by using hopping between Mn and V and the second-order effect hybrid-exchange density functional theory PBE0 and via O atoms. B3LYP. The calculated PDOS of the tetragonal struc- turehasbeeninagoodagreementwithprevioustheoret- ical results. The most important finding here is that the V. ACKNOWLEDGEMENT charge densities of spin-carrying orbitals suggest a pos- sible existence of an exotic orbital ordering: FOO along Iwouldliketoacknowledgethestimulatingdiscussions [110] and AFOO [110] in the cubic MnV2O4. The theo- with Dr. Leonardo Bernasconi, Dr. Bo Chen, and Dr. reticalpredictionpresentedherecouldbevalidatedinthe Jude Laverock. I also thank Mr. Barry Searle for tech- future experiment. 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