Zigzag Charge Ordering in α′-NaV 2O 5

Ohama, Tetsuo; Goto, Atsushi; Shimizu, Tadashi; Ninomiya, Emi; Sawa, Hiroshi; Isobe, Masahiko; Ueda, Yutaka

doi:10.1143/jpsj.69.2751

Cited by 32 publications

(40 citation statements)

References 23 publications

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“…There are eight crystallographically independent vanadium atoms, but there are only four independent sodium atoms. Despite the good fit to the diffraction data, this model is not in agreement with the observations made by NMR [20,21].…”

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confidence: 83%

“…Most notably, 23 Na NMR has found eight resonances, that were interpreted as being due to eight crystallographically independent atomic sites, whereas the crystal structure in Fmm2 only has six indepent Na sites. It was proposed that the true symmetry of the low-temperature structure might be a subgroup of Fmm2 corresponding to the loss of the F-center [21]. Alternatively, monoclinic symmetry was considered [19].…”

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confidence: 99%

“…A monoclinic distortion is ruled out, while the ordered structure with triclinic symmetry did not explain the NMR data of Refs. [20,21]. In order to accommodate observations by experimental techniques other than X-ray scattering, we propose that the true superstructure might be composed of layers with zigzag charge order on all ladders, that shows stacking disorder within a superstructure of orthorhombic symmetry, e.g.…”

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Orthorhombic versus monoclinic symmetry of the charge-ordered state ofNaV2O5

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High-resolution X-ray diffraction data show that the lowtemperature superstructure of α ′ -NaV2O5 has an F −centered orthorhombic 2a × 2b × 4c superlattice. A structure model is proposed, that is characterized by layers with zigzag charge order on all ladders and stacking disorder, such that the averaged structure has space group Fmm2. This model is in accordance with both X-ray scattering and NMR data. Variations in the stacking order and disorder offer an explanation for the recently observed devils staircase of the superlattice period along c. 61.50. Ks; 61.44.Fw; 61.66.Fn; 75.30.Fv The low dimensional transition metal oxide α ′ -NaV 2 O 5 undergoes a phase transition at a temperature of T c = 34 K. The transition is characterized by the development of both a nonmagnetic groundstate and a superstructure [1,2]. General agreement exists that the phase transition is associated with the development of charge order on the vanadium sublattice [3,4], but the mechanism of the transition has not been revealed yet.At room temperature α ′ -NaV 2 O 5 crystallizes in space group Pmmn [5][6][7]. There is one crystallographically independent vanadium atom, that is in the mixed-valence state 4.5+. The structure can be considered as built of layers of two-leg ladders V 2 O 3 , that are stacked along c, alternating with sodium atoms and additional oxygen. The lattice parameters of the basic structure at 15 K are a = 11.294Å, b = 3.604Å, and c = 4.755Å [8]. The superlattice below T c can be described by an F −centered orthorhombic 2a × 2b × 4c supercell. The superstructure was found to have symmetry F mm2, but it showed two peculiar features [8,9]: (i) In one layer ladders with zigzag charge order alternate with ladders with vanadium in the mixed-valence state, (ii) Each of the two consecutive layers contains half of the six crystallographically independent vanadium atoms, but their structures were nearly equal. This crystal structure was found to be in agreement with two other X-ray diffraction measurements [10,11].Theoretical analyses have produced models that show zigzag charge order on all ladders [3,4,[12][13][14][15][16]. However, most approaches did not consider the true supercell, and therefore they cannot be expected to reveal all aspects of the mechanism of the phase transition.Various experiments, including anomalous X-ray scat- In order to determine the true superstructure of NaV 2 O 5 , we have measured high-resolution, highsensitive synchrotron radiation X-ray diffraction. The experiment indicates that the true superlattice is F −centered on the 2a × 2b × 4c supercell. We show that an all zigzag charge order model with orthorhombic symmetry is possible assuming stacking disorder. This model is in agreement with both X-ray diffraction and NMR.X-ray diffraction experiments were performed at beamline ID10A of the ESRF in Grenoble, France. Monochromatic radiation of a wavelength of λ = 0.66057Å was selected by the 220 reflection of diamond. Bragg reflections were measured by ω−scans using a scintillation detector.N...

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Orthorhombic versus monoclinic symmetry of the charge-ordered state ofNaV2O5

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“…11 A series of recent studies has addressed the nature of the lowtemperature state [12][13][14][15][16][17] . In this context it is of interest that very recent Electron Spin Resonance (ESR) experiments 18,19 have detected a considerable anisotropy of the absorption intensity with respect to the magnetic field orientation, which has been attributed to the DM interaction.…”

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Dzyaloshinskii-Moriya interaction inNaV2O5:A microscopic study

2000

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We present a unified account of magnetic exchange and Raman scattering in the quasi-one-dimensional transitionmetal oxide NaV2O5. Based on a cluster-model approach explicit expressions for the exchange integral and the Ramanoperator are given. It is demonstrated that a combination of the electronic-structure and the Dzyaloshinskii-Moriya interaction, allowed by symmetry in this material, are responsible for the finite Raman cross-section giving rise to both, oneand two-magnon scattering amplitudes.

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“…More recent bond-valence calculations suggest, however, only two vanadium valences despite the three crystallographically inequivalent V sites [15]. Nevertheless, several observations, in particular, the properties of X-ray anomalous scattering [13], can be better explained if one assumes the modulation of all the vanadium ladders, and therefore different subgroups of F mm2 were considered [17,18]. In their Raman scattering study of folded modes, the authors of Ref.…”

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confidence: 99%

Lattice vibrations ofα′−NaV2O5
Popova
¹
,
Sushkov
²
,
Климин
³

et al. 2002
Phys. Rev. B
21
5
12
0
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We report high resolution polarized infrared studies of the quarter-filled spin ladder compound α ′ -NaV2O5 as a function of temperature (5 K≤ T ≤ 300 K). Numerous new modes were detected below the temperature Tc = 34 K of the phase transition into a charge ordered nonmagnetic state accompanied by a lattice dimerization. We analyse the Brillouin zone (BZ) folding due to lattice dimerization at Tc and show that some peculiarities of the low-temperature vibrational spectrum come from quadruplets folded from the BZ point ( ). We discuss an earlier interpretation of the 70, 107, and 133 cm −1 modes as magnetic bound states and propose the alternative interpretation as folded phonon modes strongly interacting with charge and spin excitations.

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Zigzag Charge Ordering in α^′-NaV₂O₅

Cited by 32 publications

References 23 publications

Orthorhombic versus monoclinic symmetry of the charge-ordered state ofNaV2O5

Orthorhombic versus monoclinic symmetry of the charge-ordered state ofNaV2O5

Dzyaloshinskii-Moriya interaction inNaV2O5:A microscopic study

Lattice vibrations ofα′−NaV2O5
Popova
¹
,
Sushkov
²
,
Климин
³

et al. 2002
Phys. Rev. B
21
5
12
0
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Zigzag Charge Ordering in α′-NaV 2O 5

Cited by 32 publications

References 23 publications

Orthorhombic versus monoclinic symmetry of the charge-ordered state ofNaV2O5

Orthorhombic versus monoclinic symmetry of the charge-ordered state ofNaV2O5

Dzyaloshinskii-Moriya interaction inNaV2O5:A microscopic study

Lattice vibrations ofα′−NaV2O5Popova1, Sushkov2, Климин3 et al. 2002Phys. Rev. B215120View full textAdd to dashboardCite

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Zigzag Charge Ordering in α^′-NaV₂O₅

Lattice vibrations ofα′−NaV2O5
Popova
¹
,
Sushkov
²
,
Климин
³

et al. 2002
Phys. Rev. B
21
5
12
0
View full text Add to dashboard Cite