High-temperature weak ferromagnetism in a low-density free-electron gas

Young, David P.; Hall, D.; Torelli, M. E.; Fisk, Z.; Sarrao, J. L.; Thompson, J. D.; Ott, H. R.; Oseroff, S. B.; Goodrich, R. G.; Zysler, R.D.

doi:10.1038/17081

Cited by 438 publications

(316 citation statements)

References 12 publications

(9 reference statements)

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“…The Ir moment is much lower than expected for the low spin S 1=2; 2 T 2g state of Ir 4ϩ (5d 5 ) which has degenerate d xz and d yz orbitals and an excited half filled d xy orbital, but both T C and the moment value are in substantial agreement with the results of Lindsay et al [4] for polycrystalline material. Similar low Ir moments are found for ferromagnetic Sr 2 IrO 4 T C 250 K; m eff 0:04m B =Ir as well as for CaIrO 3 and Ca 2 IrO 4 [7,12].…”

supporting

confidence: 65%

“…The non-hysteretic large main feature of non-linearity of the I-V characteristics may be due to an electrothermal effect which can occur in systems with dr T =dT Ͻ 0 if the heat sinking to ambient temperature is insufficient to remove joule heating. (Recently, Young et al [12] found T C Ϸ 600 K and Ϸ0.001m B /x in Ca 1Ϫx La x B 6 for x Ϸ 0:005: Whether a similar dilute electronic gas mechanism accounts for the iridate anomalies remains an open question.) However, the sharp, hysteretic feature in Fig.…”

mentioning

confidence: 99%

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Charge density wave formation accompanying ferromagnetic ordering in quasi-one-dimensional BaIrO3

Cao

Crow

Guertin

et al. 2000

Solid State Communications

110

142

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The magnetic, transport, optical, and structural properties of quasi-one-dimensional BaIrO 3 show evidence for the simultaneous onset of electronic density wave formation and ferromagnetism at T c3 175 K: Two additional features in the chain direction dc conductivity show a sudden change to metallic behavior below T c2 80 K and then a Mott-like transition at T c1 26 K: Highly non-linear dc conductivity, optical gap formation at Ϸ9k B T c3 , additional phonon modes, and emergent X-ray satellite structure support density wave formation. Even at very high (30 T) fields the saturation Ir moment is very small, Ϸ0.04m B /Ir. ᭧ 2000 Elsevier Science Ltd. All rights reserved. Transition metal oxides (TMO) with low crystalline symmetry are known to exhibit electronic density wave formation [1][2][3]. However, to our knowledge, density wave formation has not yet been observed accompanying the onset of ferromagnetic order. However, the ferromagnetism at T c3 175 K in BaIrO 3 [4] appears to be accompanied by and possibly driven by a collective electronic excitation or at least partial gapping of the Fermi surface. This demonstrates once again the strong coupling between spin and charge in the heavy (4d-and 5d-based) TMOs [5][6][7]. BaIrO 3 has a highly anisotropic quasi-one-dimensional structure [8][9][10] and this gives rise, in our single crystal samples, to large anisotropy of r(T), the electrical resistivity, with the quasi-one-dimensional axis, the c-axis, having much lower resistivity. This kind of low-dimensional structure is necessary for the formation of an insulating charge density wave (CDW) ground state, which is a collective electron mode normally incommensurate with the underlying lattice for partially filled bands [3].Evidence for density wave formation comes from: (1) A discontinuous increase in the slope of r (T) vs. T at T c3 T C ; the Curie temperature-an abrupt transition to a more insulating phase. (Two additional features of r (T) along the c-axis, at T c2 80 K and T c1 26 K; mark a sudden return to "metallic" behavior (possibly a crossover from partial toward full gapping of the Fermi surface) and a well-defined Mott-like metal-insulator transition, respectively). (2) An abrupt feature in the non-linear conductivity showing negative differential resistivity. (3) Gap formation at about 1200 cm Ϫ1 in the electron excitation spectrum and a splitting of a phonon mode at 350 cm Ϫ1 , which appear for T Ͻ T c3 (This was determined by optical reflectivity studies in the far and near infrared.). (4) Additional satellite formation for T Ͻ T C3 in the X-ray diffraction spectrum.The structure of BaIrO 3 is monoclinic and consists of Ir 3 O 12 trimers of face-sharing IrO 6 octahedra which are vertex-linked to other trimeric clusters forming columns roughly parallel to the c-axis. These clusters form channels accommodating Ba ions. The space group is C2/m and the

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supporting

confidence: 65%

mentioning

confidence: 99%

Charge density wave formation accompanying ferromagnetic ordering in quasi-one-dimensional BaIrO3

Cao

Crow

Guertin

et al. 2000

Solid State Communications

110

142

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“…Recently, it has been found that CaB 6 or SrB 6 with low densities of trivalent Eu or quadrivalent Ce ions substituting for (Ca; Sr) are ferromagnets [295]. The most plausible explanation [303,34,36] is that this is a realization of the excitonic ferromagnetism predicted by Volkov et al [279].…”

Section: Routes To Breakdown Of Landau Theorymentioning

confidence: 99%

“…A model band structure for a solid with more than one atom per unit cell. Actually in CaB 6 where excitonic singularities have been invoked to produce a ferromagnetic state [295] there are three equivalent points in the Brillouin zone where the conduction band minima and the valence band maxima occur.…”

Section: Routes To Breakdown Of Landau Theorymentioning

confidence: 99%

Singular or non-Fermi liquids

2002

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“…Dilute ferromagnetism in oxide semiconductors generally has been reported with 3d dopants in ZnO particularly with Mn, Co, Ni, Fe, Cu, and V dopings. [1][2][3] Unexpected magnetization without transition metal has been reported in dielectric oxides such as HfO 2 , ZrO 2 , 4 and nonmagnetic oxides, e.g., ZnO, 5 hexaborides, 6 carbon-doped ZnO, 7 and in irradiated graphite. 8 The theory of Dietl et al 9 suggests that carrier-induced ferromagnetism in Mn-doped p-type material may be observed at higher temperature.…”

Section: Introductionmentioning

confidence: 99%

Room-temperature ferromagnetism in Li-dopedp-type luminescent ZnO nanorods

2009

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We have observed ferromagnetism in Li-doped ZnO nanorods with Curie temperature up to 554 K. Li forms shallow acceptor states in substitutional zinc sites giving rise to p-type conductivity. An explicit correlation emerges between increase in hole concentration with decrease in magnetization and Curie temperature in ZnO:Li. Occurrence of ferromagnetism at room temperature has been established with observed magnetic domain formation in ZnO:Li pellets in magnetic force microscopy and prominent ferromagnetic resonance signal in electron paramagnetic resonance spectrum. Magnetic ZnO:Li nanorods are luminescent, showing strong near UV emission. Substitutional Li atoms can induce local moments on neighboring oxygen atoms, which when considered in a correlated model for oxygen orbitals with random potentials introduced by dopant atom could explain the observed ferromagnetism and high Curie temperature in ZnO:Li nanorods.

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High-temperature weak ferromagnetism in a low-density free-electron gas

Cited by 438 publications

References 12 publications

Charge density wave formation accompanying ferromagnetic ordering in quasi-one-dimensional BaIrO3

Charge density wave formation accompanying ferromagnetic ordering in quasi-one-dimensional BaIrO3

Singular or non-Fermi liquids

Room-temperature ferromagnetism in Li-dopedp-type luminescent ZnO nanorods

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