Magnetization and Spin Correlation of Two-Dimensional Triangular Antiferromagnet LuFe<sub>2</sub>O<sub>4</sub>

Iida, Junji; Tanaka, Midori; Nakagawa, Yasuaki; Funahashi, Satoru; Kimizuka, Noboru; Takekawa, Shunji

doi:10.1143/jpsj.62.1723

Cited by 119 publications

(117 citation statements)

References 14 publications

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“…Magnetic measurements were carried out between 5 and 300 K using a commercial Quantum Design superconducting quantum interference device (SQUID) magnetometer. Figure 1 shows the temperature dependence of the zero-field-cooled (ZFC) and field-cooled (FC) magnetization for various RFe 2 O 4 samples (R = Lu, Yb, Tm) and applied magnetic field (H) of either 4 T or 5 T. The ZFC-FC magnetic irreversibility at low temperatures and the strong anisotropy with an easy magnetic direction parallel to the crystallographic c axis agree with previous reports in the literature [13][14][15][16]. We would like to emphasize that magnetization reversal can only be achieved, for a given H, at temperatures where the ZFC-FC curves overlap.…”

Section: Introductionsupporting

confidence: 85%

“…On the other hand, the YFe 2 O 4 compound shows a complex low temperature structure with various crystal distortions coupled * E-mail: sara.lafuerza@esrf.fr to two successive Verwey-type metal-insulator transitions at about 240 and 190 K [11,12] not observed in the Lu, Yb, and Tm compounds. Concerning the magnetic properties, LuFe 2 O 4 [13,14], YbFe 2 O 4 [15], and TmFe 2 O 4 [16] exhibit ferrimagnetic ordering below T N ≈ 240−250 K, whereas the YFe 2 O 4 compound is antiferromagnetic [11].…”

Section: Introductionmentioning

confidence: 99%

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Electronic states ofRFe2O4(R=Lu,Yb,Tm
Lafuerza
¹
,
García
²
,
Subı́as
³

et al. 2014
Phys. Rev. B
10
2
4
1
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We here report an investigation of the electronic states in the RFe 2 O 4 (R = Lu, Yb, Tm, Y) mixed-valence ferrites by means of soft x-ray absorption spectroscopy (XAS) and x-ray magnetic circular dichroism (XMCD) measurements together with ab initio theoretical calculations. The presence of Fe +2 and Fe +3 pure ionic species is discarded in the XAS spectra at the O K edge in both experimental data and simulations based on the multiple scattering theory. Similarly, no trace of Fe +2 /Fe +3 contributions is detected in the XMCD spectra at the Fe K edge. On the other hand, the XAS and XMCD spectra at the Fe L 2,3 edges can be well described in terms of Fe +2 /Fe +3 contributions, and are also supported by multiplet calculations. This finding can be interpreted as the existence of a mixture of 3d 5 /3d 6 configurations at the Fe atoms. Alternative ferrimagnetic spin orderings based on a trimodal Fe valence distribution are also proposed and discussed. Finally, a possible explanation for the strong dependence of the Fe L 2,3 edges XMCD signal magnitude on both the sample surface preparation and detection method is presented.

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Section: Introductionsupporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Electronic states ofRFe2O4(R=Lu,Yb,Tm
Lafuerza
¹
,
García
²
,
Subı́as
³

et al. 2014
Phys. Rev. B
10
2
4
1
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“…The strong magnetic anisotropy with an easy magnetic axis parallel to the c axis, the ZFC-FC magnetic irreversibility in both geometries, and the sharp magnetic transition below 240 K are in accordance with previous reports in the literature. 11,[27][28][29] Electrical dc resistivity measurements were made on sintered polycrystalline bar-shaped samples (ρ pol ) with a size of 1 × 2 × 6 mm 3 and on single-crystal bar-shaped samples of a size of 0.5 × 0.6 × 1 mm 3 and 0.5 × 1 × 4 mm 3 with the electric field parallel (ρ c ) and perpendicular (ρ ab ) to the hexagonal c axis. The conventional four-probe configuration was used and electrodes were made using silver paint.…”

Section: Methodsmentioning

confidence: 99%

“…9 LuFe 2 O 4 undergoes successive phase transitions. 2D charge correlations are observed below 500 K, while the ferroelectric phase transition is proposed to coincide with a 3D Fe 3+ /Fe 2+ CO below 320 K. 4,5,10 This is followed by ferrimagnetic order below T N ∼ 240 K. 2,[11][12][13] The general claim about ferroelectricity in LuFe 2 O 4 has been based on the following experimental results: (i) the observation of giant dielectric constant at temperatures above 150 K, [4][5][6] and (ii) the measurement of the pyroelectric current after field polarization. 4,5,14 The colossal dielectric properties reported for LuFe 2 O 4 (Refs.…”

Section: Introductionmentioning

confidence: 97%

Intrinsic electrical properties of LuFe2O4

et al. 2013

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We here revisit the electrical properties of LuFe 2 O 4 , compound candidate for exhibiting multiferroicity. Measurements of dc electrical resistivity as a function of temperature, electric-field polarization measurements at low temperatures with and without magnetic field, and complex impedance as a function of both frequency and temperature were carried out in a LuFe 2 O 4 single crystal, perpendicular and parallel to the hexagonal c axis, and in several ceramic polycrystalline samples. Resistivity measurements reveal that this material is a highly anisotropic semiconductor, being about two orders of magnitude more resistive along the c axis. The temperature dependence of the resistivity indicates a change in the conduction mechanism at T CO ≈ 320 K from thermal activation above T CO to variable range hopping below T CO . The resistivity values at room temperature are relatively small and are below 5000 cm for all samples but we carried out polarization measurements at sufficiently low temperatures, showing that electric-field polarization curves are a straight line as expected for a paraelectric or antiferroelectric material. Furthermore, no differences are found in the polarization curves when a magnetic field is applied either parallel or perpendicular to the electric field. The analysis of the complex impedance data corroborates that the claimed colossal dielectric constant is a spurious effect mainly derived from the capacitance of the electrical contacts. Therefore, our data unequivocally evidence that LuFe 2 O 4 is not ferroelectric.

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“…The high-temperature crystal structure of LuFe 2 O 4 belongs to the rhombohedral system with space group R3m [30,31] and it is usually described in the hexagonal setting where it can be seen as a stacking of [Fe 2 O 4 shows two phase transitions upon cooling down: first the so-called CO transition ascribed to the ordering of the Fe 3+ and Fe 2+ ions at T CO 320 K [3,5,6] and secondly another transition to a ferrimagnetic ordering that takes place at T C 240 K [32,33]. The CO phase in LuFe 2 O 4 was first characterized by the occurrence of superlattice reflections with (1/3,1/3,l/2) hexagonal Miller indices (from here on, the hexagonal setting is used).…”

Section: Introductionmentioning

confidence: 99%

Determination of the sequence and magnitude of charge order inLuFe2O4by resonant x-ray scattering

et al. 2014

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We have investigated the low-temperature phases of LuFe 2 O 4 by resonant x-ray scattering (RXS) at the Fe K edge to determine both the ordering sequence and magnitude of charge segregation. Two successive charge ordering (CO) phases have been detected. Resonant superlattice (1/3,1/3,l/2) reflections appear below the so-called CO phase at T CO 320 K. Additionally, resonant superlattice (1/3,1/3,l) reflections are observed below 240 K concurrent with the onset of the magnetic ordering. The σ -σ polarization dependence for all the measured superlattice reflections indicates the absence of local anisotropy of the electronic density at the Fe atom. The energy dependence of the resonant intensity for these reflections has been quantitatively analyzed following the monoclinic C2/m structure in the CO phase between 320 and 240 K and the triclinic P1 structure below 240 K. We find a four-modal charge segregation among the Fe atoms in the C2/m phase with formal valences Fe 2.77+ , Fe 2.63+ , Fe 2.36+ , and Fe 2.22+ whereas the simplest charge distribution that explains successfully all the RXS data in the P1 phase is the trimodal Fe 2.8+ , Fe 2.5+ , and Fe 2.2+ . Both ordering models imply the lack of charge segregation along the c axis discarding a polar configuration and thus the occurrence of ferroelectricity.

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Magnetization and Spin Correlation of Two-Dimensional Triangular Antiferromagnet LuFe₂O₄

Cited by 119 publications

References 14 publications

Electronic states ofRFe2O4(R=Lu,Yb,Tm
Lafuerza
¹
,
García
²
,
Subı́as
³

et al. 2014
Phys. Rev. B
10
2
4
1
View full text Add to dashboard Cite

Electronic states ofRFe2O4(R=Lu,Yb,Tm
Lafuerza
¹
,
García
²
,
Subı́as
³

et al. 2014
Phys. Rev. B
10
2
4
1
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Intrinsic electrical properties of LuFe2O4

Determination of the sequence and magnitude of charge order inLuFe2O4by resonant x-ray scattering

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Magnetization and Spin Correlation of Two-Dimensional Triangular Antiferromagnet LuFe2O4

Cited by 119 publications

References 14 publications

Electronic states ofRFe2O4(R=Lu,Yb,TmLafuerza1, García2, Subı́as3 et al. 2014Phys. Rev. B10241View full textAdd to dashboardCite

Electronic states ofRFe2O4(R=Lu,Yb,TmLafuerza1, García2, Subı́as3 et al. 2014Phys. Rev. B10241View full textAdd to dashboardCite

Intrinsic electrical properties of LuFe2O4

Determination of the sequence and magnitude of charge order inLuFe2O4by resonant x-ray scattering

Contact Info

Product

Resources

About

Magnetization and Spin Correlation of Two-Dimensional Triangular Antiferromagnet LuFe₂O₄

Electronic states ofRFe2O4(R=Lu,Yb,Tm
Lafuerza
¹
,
García
²
,
Subı́as
³

et al. 2014
Phys. Rev. B
10
2
4
1
View full text Add to dashboard Cite

Electronic states ofRFe2O4(R=Lu,Yb,Tm
Lafuerza
¹
,
García
²
,
Subı́as
³

et al. 2014
Phys. Rev. B
10
2
4
1
View full text Add to dashboard Cite