Magnetic phase diagram of single crystals

Wu, Tao; Wu, Gang; Chen, Hanjie; Liu, R. H.; Wang, X. F.; Chen, X.H.

doi:10.1016/j.jmmm.2009.07.043

Cited by 17 publications

(15 citation statements)

References 25 publications

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“…For the parent compound, two anomalies in resistivity are observed at 188 K and 20 K, respectively. They arise from the SDW/structural transitions and the AFM order of local moments for Eu 2+ ions [17]. The resistivity anomaly arose from the the SDW/structural transition is gradually suppressed with increasing the doping x, while the anomaly around 20 K due to the antiferromagnetic transition of Eu 2+ ions nearly does not change by varying the La doping.…”

Section: +2mentioning

confidence: 96%

Section: +mentioning

confidence: 99%

“…In the latter case, earlier results on Eu 1−x La x Fe 2 As 2 shows only gradual decrease of the spin density wave transition temperature, T SDW , of F e spins with increasing the La content. No superconducting transition was observed [17] and no information regarding of the role of Eu +2 spins has been * Corresponding author; Electronic address: chenxh@ustc.edu.cn provided.High pressure is confirmed to be good method to tune the phase competition of superconductivity and SDW in iron-pnicides superconductors. In this letter, we systematically investigate the superconductivity in La doped EuFe 2 As 2 system under ambient and high pressure by resistivity and magnetic susceptibility measurements.…”

mentioning

confidence: 99%

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Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2
Zhang
¹
,
Ying
²
,
Yan
³

et al. 2012
Phys. Rev. B
12
1
9
0
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We establish the phase diagram of Eu1−xLaxFe2As2 system as a function of doping level x and the pressure by measuring the resistivity and magnetic susceptibility. The pressure can suppress the spin density wave (SDW) and structural transition very efficiently, while enhance the antiferromagnetic (AFM) transition temperature TN of Eu 2+ . The superconductivity coexists with SDW order at the low pressure, while always coexists with the Eu 2+ AFM order. The results suggests that Eu 2+spin dynamics is disentangeld with superconducting (SC) pairing taken place in the two-dimensional Fe-As plane, but it can strongly affect superconducting coherence along c-axis.PACS numbers: 74.25. 74.25.Ha, Iron-based superconductors have attracted great attentions these years [1][2][3][4]. The parent compound undergoes structural and spin density wave (SDW) transitions. With chemical doping or high pressure, both structural and SDW transition can be suppressed and superconductivity emerges. AFe 2 As 2 (A=Ca, Sr, Ba, Eu) with the T hCr 2 Si 2 -type structure were widely investigated because it is easy to grow large size of high quality single crystals [5]. The maximum T C for the holedoped samples is about 38 K and for the Co doped samples the maximum T C is about 26 K [4,6]. Recently, superconductivity up to 49 K was discovered in rare earth doped CaFe 2 As 2 , it is the highest T C observed in 122 system [7][8][9][10]. EuFe 2 As 2 has the same structure as that of CaFe 2 As 2 [11]. EuFe 2 As 2 shows superconductivity around 31 K under the pressure of 3 GPa[12].The Eu122 system has an intriguingly outstanding issue regarding the interplay between the magnetism of large Eu +2 spins and the superconductivity. The doping on the Eu122 system has been achieved in two ways: direct electron doping on Fe-As layer, such as Co-doped Eu122, and doping induced by Eu replacement with rare earth atoms such as Eu 1−x La x Fe 2 As 2 . In the former case, a resistivity reentrance due to AFM order of Eu +2 spins was often observed [13][14][15][16], an indication of the effect of Eu 2+ spins on superconductivity. However, a clear understanding of such an effect has not been established due to lacking of systematic investigation. In the latter case, earlier results on Eu 1−x La x Fe 2 As 2 shows only gradual decrease of the spin density wave transition temperature, T SDW , of F e spins with increasing the La content. No superconducting transition was observed [17] and no information regarding of the role of Eu +2 spins has been * Corresponding author; Electronic address: chenxh@ustc.edu.cn provided.High pressure is confirmed to be good method to tune the phase competition of superconductivity and SDW in iron-pnicides superconductors. In this letter, we systematically investigate the superconductivity in La doped EuFe 2 As 2 system under ambient and high pressure by resistivity and magnetic susceptibility measurements. We obtain a complete phase diagram. obtained. It is found that one superconducting transition was observed in the highest doping level ...

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Section: +2mentioning

confidence: 96%

Section: +mentioning

confidence: 99%

mentioning

confidence: 99%

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Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2
Zhang
¹
,
Ying
²
,
Yan
³

et al. 2012
Phys. Rev. B
12
1
9
0
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“…1͒. [26][27][28][29][30] To reach a comprehensive picture of the complex electronic structure in the SDW state of iron pnictides and reveal the manifestation of various magnetic orderings on the electronic structure, we have performed the ARPES measurements of EuFe 2 As 2 single crystals. Two hole Fermi pockets around ͑0,0͒ and two electron pockets around ͑ , ͒ are observed in the high-temperature paramagnetic ͑PM͒ state.…”

Section: Introductionmentioning

confidence: 99%

High-resolution angle-resolved photoemission spectroscopy study of the electronic structure ofEuFe2As2

et al. 2010

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We report the high-resolution angle-resolved photoemission spectroscopy studies of electronic structure of EuFe 2 As 2 . The paramagnetic state data are found to be consistent with density-functional calculations. In the antiferromagnetic ordering state of Fe, our results show that the band splitting, folding, and hybridization evolve with temperature, which cannot be explained by a simple folding picture. Detailed measurements reveal that a tiny electron Fermi pocket and a tiny hole pocket are formed near ͑ , ͒ in the ͑0,0͒ − ͑ , ͒ direction, which qualitatively agree with the results of quantum oscillations, considering k z variation in Fermi surface. Furthermore, no noticeable change within the energy resolution is observed across the antiferromagnetic transition of Eu 2+ ordering, suggesting weak coupling between Eu sublattice and FeAs sublattice.

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“…5. From the behavior of this curve and estimations it follows that the condition ξ(H)/L N (F) ≥ 1 is violated in the fields higher than about 2 kOe: where λ B and R L are the de Broglie wavelength and the Larmor radius, respectively, for LaO(F)FeAs the Fermi velocity of which is v F ≈ 10 7 cm/s [19]. Thus, in fields higher than 2 kOe the behavior of magnetoresistance in contact with N (F) area, about 0.2 µ in thickness, at 1 mA and T < T c could qualitatively obey the following pattern:…”

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confidence: 94%

Spin-dependent conductivity of iron-based superconductors in a magnetic field

Dzyuba¹,

Chiang²,

Чареев³

et al. 2015

Physica B: Condensed Matter

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We report the results of a study of magnetic field features of electron transport in heterojunctions with NS boundary inside iron-based superconductors, represented by a binary phase of α -FeSe and oxyarsenide pnictide LaO(F)FeAs. We used the ability of self magnetic field of the transport current to partially destroy superconductivity, no matter how low the field may be, in the NS interface area, where, due to the proximity effect, the superconducting order parameter, ∆, disperses from 1 to 0 within the scale of the Ginzburg-Landau coherence length.The following features of transport were found: (i) at T < T c , magnetoresistance in systems with different superconductors has different sign; (ii) sign and magnitude of the magnetoresistance depend on the magnitude of current and temperature, and (iii) in all operating modes where the contribution from Andreev reflection is suppressed ((T + eV ) ∆), the hysteresis of the magnetoresistance is present.Based on the results of the experiment and analysis it has been concluded that there is a longrange magnetic order in the ground normal state of the iron-based superconductors studied, in the presence of itinerant magnetism of conduction electrons which determines the possibility of anisotropic spin-dependent exchange interaction with the local magnetic moments of the ions.Search and study of low-symmetry systems with crystal symmetry of "layered" type, characterized by anisotropic electrical and magnetic properties leading to superconductivity, is one of the most urgent problems of condensed matter physics. Currently, superconductivity is found in the vast family of such compounds containing a wide range of rare earths, pnictogens, chalcogens, and transition elements Mn, Fe, Co, Ni, Cu, Ru. In particular, observation of superconductivity in iron-based structures suggests that it is the anisotropy of the properties that seems to be an essential condition under which in the same material may coexist magnetic interactions and interactions that determine the superconducting pairing of excitations in the electronic subsystem.While the ideas of the crystal structures and nature of coupling in such superconductors are sufficiently developed and experimentally proved, their magnetic and electronic structures, and especially the nature of their interaction in the ground state of iron-based superconductors, are still the subject of intense debate (see, eg, [1, 2]). Therefore, it becomes important to study transport phenomena in the systems containing such superconductors, as the nature of those phenomena may directly depend on itinerant magnetism of conduction electrons, capable of interacting with the sublattice of localized magnetic moments of the magnetic atoms.Here we report the results of studying hysteresis features of electron transport in a magnetic field in the normal ground state of iron-based superconductors, namely, monocrystalline binary phase of α -FeSe and oxyarsenide pnictide LaO(F)FeAs in granular form. Both crystal structures share common structural un...

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Magnetic phase diagram of single crystals

Cited by 17 publications

References 25 publications

Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2
Zhang
¹
,
Ying
²
,
Yan
³

et al. 2012
Phys. Rev. B
12
1
9
0
View full text Add to dashboard Cite

Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2
Zhang
¹
,
Ying
²
,
Yan
³

et al. 2012
Phys. Rev. B
12
1
9
0
View full text Add to dashboard Cite

High-resolution angle-resolved photoemission spectroscopy study of the electronic structure ofEuFe2As2

Spin-dependent conductivity of iron-based superconductors in a magnetic field

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Magnetic phase diagram of single crystals

Cited by 17 publications

References 25 publications

Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2Zhang1, Ying2, Yan3 et al. 2012Phys. Rev. B12190View full textAdd to dashboardCite

Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2Zhang1, Ying2, Yan3 et al. 2012Phys. Rev. B12190View full textAdd to dashboardCite

High-resolution angle-resolved photoemission spectroscopy study of the electronic structure ofEuFe2As2

Spin-dependent conductivity of iron-based superconductors in a magnetic field

Contact Info

Product

Resources

About

Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2
Zhang
¹
,
Ying
²
,
Yan
³

et al. 2012
Phys. Rev. B
12
1
9
0
View full text Add to dashboard Cite

Phase diagram as a function of doping level and pressure in the Eu1−xLaxFe2
Zhang
¹
,
Ying
²
,
Yan
³

et al. 2012
Phys. Rev. B
12
1
9
0
View full text Add to dashboard Cite