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Details of 3D electronic structure of some Fe-based superconductors and their superconducting order parametersKushnirenko, Yevhen S. 08 January 2020 (has links)
In this thesis, the results of analyzing the electronic structure of two iron-based superconductors: FeSe and LiFeAs are presented. To access the electronic structure, angle-resolved photoemission spectroscopy was used. In our analysis, we focus on the structure of the superconducting gap and the influence of nematicity on the electronic structure.
We have revealed changes in the electronic structure of FeSe caused by nematicity in all parts of the Brillouin zone. A scale of these changes is smaller than it was believed earlier. Also, we have observed an anomalous shift of the dispersions in opposite directions with temperature in this material. We have observed anisotropic superconducting gap on all sheets of the Fermi surfaces of both: FeSe and LiFeAs. We have shown that in LiFeAs, rotational symmetry is broken in the superconducting state, which manifests not only in the gap symmetry but also in the shapes of the Fermi surfaces sheets. This result indicates a realization of a novel phenomenon of superconductivity-induced nematicity:1 Iron-based superconductors
1.1 Introduction to iron-based superconductors
1.2 LiFeAs - special iron-based superconductor
1.3 FeSe - structurally simplest iron-based superconductor
2 Angle-Resolved Photoemission
3 Temperature evolution of the electronic structure of FeSe
3.1 Effects of nematicity from low-temperature measurements
3.2 Temperature dependent shift of the dispersions
3.3 Discussion and conclusions
4 Three-dimensional superconducting gap in FeSe
4.1 Superconducting gap on the electron-like pockets
4.2 Superconducting gap on the hole-like pocket
4.3 Discussion and conclusions
5 Superconductivity-induced nematicity in LiFeAs
5.1 Superconducting gap
5.2 Nematicity
5.3 Discussion and conclusions
Summary
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Effect of impurity scattering and electron correlations on quasiparticle excitations in iron-based superconductors / 鉄系超伝導体における不純物散乱と電子相関の準粒子励起への影響Mizukami, Yuta 23 March 2016 (has links)
京都大学 / 0048 / 新制・論文博士 / 博士(理学) / 乙第12996号 / 論理博第1552号 / 新制||理||1604(附属図書館) / 32924 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 松田 祐司, 教授 前野 悦輝, 教授 石田 憲二 / 学位規則第4条第2項該当 / Doctor of Science / Kyoto University / DGAM
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Quasiparticle excitations in FeSe in the vicinity of BCS-BEC crossover studied by thermal transport measurements / FeSe単結晶における熱輸送係数の測定Watashige, Tatsuya 23 March 2017 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20166号 / 理博第4251号 / 新制||理||1611(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 松田 祐司, 教授 川上 則雄, 教授 前野 悦輝 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM
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Nuclear Magnetic Resonance Studies on Iron Chalcogenide FeSe / 鉄カルコゲン化物FeSeの核磁気共鳴による研究Shi, Anlu 23 May 2018 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第21247号 / 理博第4417号 / 新制||理||1634(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 石田 憲二, 教授 前野 悦輝, 教授 松田 祐司 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
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Studies on Iron Chalcogenide by Mossbauer Spectroscopy and Nuclear Resonant Inelastic Scattering / メスバウアー分光と核共鳴非弾性散乱による鉄カルコゲン化合物の研究Kurokuzu, Masayuki 24 March 2014 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18067号 / 理博第3945号 / 新制||理||1568(附属図書館) / 30925 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 瀬戸 誠, 教授 鶴 剛, 教授 大久保 嘉高 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM
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NMR STUDY OF THE POTASSIUM IRON SELENIDE HIGH-TEMPERATURE SUPERCONDUCTORTorchetti, David 10 1900 (has links)
<p>In this thesis we present a <sup>77</sup>Se NMR study of the iron selenide based high-temperature superconductor K<sub>x</sub>Fe<sub>2−y</sub>Se<sub>2</sub> (T<sub>c</sub> = 33 K). We observe NMR lineshapes as narrow as ∼ 4.5 kHz with an applied field along the crystal c-axis, and find no evidence for the co-existence of magnetic order with superconductivity. With an applied field along the ab plane, however, the lineshape splits into two peaks of equal intensities at all temperatures, suggesting that the tetragonal fourfold symmetry of the average structure may be locally lowered by vacancy superstructure. Knight shift data indicate that spin susceptibility decreases progressively with temperature, similar to other iron arsenide high-T<sub>c</sub> systems. In the nuclear spin-lattice relaxation rate 1/T<sub>1</sub> we observe no Hebel-Slichter coherence peak, nor any enhancement in low frequency antiferromagnetic spin fluctuations in 1/T<sub>1</sub>T. We also report on the effects of sulphur (S) substitution on the selenium sites in this system by conducting <sup>77</sup>Se NMR measurements on K<sub>x</sub>Fe<sub>2−y</sub>Se<sub>2−z</sub>S<sub>z</sub> (z = 0.8, 1.6). We find that both spin susceptibility and low frequency spin fluctuations are suppressed with increasing S content along with T<sub>c</sub>.</p> / Master of Science (MSc)
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Theoretical studies of topology and strong correlations in superconductorsHazra, Tamaghna January 2020 (has links)
No description available.
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Electronic phase diagrams and competing ground states of complex iron pnictides and chalcogenidesKamusella, Sirko 29 March 2017 (has links) (PDF)
In this thesis the superconducting and magnetic phases of LiOH(Fe,Co)(Se,S), CuFeAs/CuFeSb, and LaFeP_1-xAs_xO - belonging to the 11, 111 and 1111 structural classes of iron-based arsenides and chalcogenides - are investigated by means of 57Fe Mössbauer spectroscopy and muon spin rotation/relaxation (μSR). Of major importance in this study is the application of high magnetic fields in Mössbauer spectroscopy to distinguish and characterize ferro- (FM) and antiferromagnetic (AFM) order. A user-friendly Mössbauer data analysis program was developed to provide suitable model functions not only for high field spectra, but relaxation spectra or parameter distributions in general.
In LaFeP_1-xAs_xO the reconstruction of the Fermi surface is described by the vanishing of the Γ hole pocket with decreasing x. The continuous change of the orbital character and the covalency of the d-electrons is shown by Mössbauer spectroscopy. A novel antiferromagnetic phase with small magnetic moments of ~ 0.1 μ_B state is characterized. The superconducting order parameter is proven to continuously change from a nodal to a fully gapped s-wave like Fermi surface in the superconducting regime as a function of x, partially investigated on (O,F) substituted samples.
LiOHFeSe is one of the novel intercalated FeSe compounds, showing strongly increased T_C = 43 K mainly due to increased interlayer spacing and resulting two-dimensionality of the Fermi surface. The primary interest of the samples of this thesis is the simultaneously observed ferromagnetism and superconductivity. The local probe techniques prove that superconducting sample volume gets replaced by ferromagnetic volume. Ferromagnetism arises from magnetic order with T_C = 10 K of secondary iron in the interlayer. The tendency of this system to show (Li,Fe) disorder is preserved upon (Se,S) substitution. However, superconductivity gets suppressed. The results of Mössbauer spectroscopy indicate that the systems tends to a secondary structural phase, where the local iron environment observed in pure FeS is absent. Moreover, two interlayer positions of the iron are identified. The absence of enhanced superconducting T_C in LiOHFeS thus is related to a structural instability.
Also, in CuFeAs the role of secondary iron at the Cu position turns out to be decisive for the observed magnetic behaviour. As in LiOHFeSe, it orders ferromagnetically at T_C ~ 11 K and superimposes with the magnetic instability of the main iron site. It is shown that a small charge doping of 0.1e/Fe, which is expected from (Cu,Fe) disorder, is sufficient to switch the system between a paramagnetic and an AFM ground state. Both magnetic orders are indistinguishable, because the magnetic order parameters are strongly coupled. This coupling was observed in the structurally identical CuFeSb, where the magnetic order parameters of both iron sites scale perfectly. The magnetically unstable CuFeAs and the ferromagnetic CuFeSb can be classified according to the theory of As height driven magnetism, predicting a change from paramagnetism to AFM and finally FM with increasing As height.
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Recherche sur les propriétés supraconductrices des supraconducteurs à base de Fer 122 par mesure de transport et microscopie à squid / The superconducting properties research of iron based-122 by transport and scanning micro-squid measurementsWang, Zhao-Sheng 26 May 2012 (has links)
Plus de vingt ans après la découverte de la supraconductivité à haute température critique, le mécanisme physique sous-jacente n'est pas encore bien cerné. En 2008, la découverte d'une nouvelle famille de supraconducteurs à haute température critique, les supraconducteurs à base de fer, a donné l'espoir de trouver une compréhension plus profonde des mécanismes de ce type de supraconductivité. Synthétiser des l'échantillons de grande qualité, la caractérisation des propriétés supraconductrices, l'étude des symétrices du gap et du paramètre d'ordre sont des étapes essentielles pour révéler le mécanisme. La connaissance précise du mécanisme permettra de profiter pleinement des propriétés remarquables de ces matériaux dans leurs applications industrielles si prometteuses. La thèse décrit d'abord la croissance de monocristaux de Ba$_{1-x}$K$_x$Fe$_2$As$_2$ et l'étude de leurs propriétés supraconductrices, menant vers la proposition d'une structure de gap du supraconducteur et d'un paramètre d'ordre pour les supraconducteurs à base de fer Ba-122 à partir de mesures de résistivité, de sondes à effect Hall, de spectroscopie d'Andreev en mode point-contact et de l'imagerie magnétique par la microscopie à nano-squid.Dans le chapitre 1, les événements historiques les plus marquants de la supraconductivité sont rappelés, les propriétés essentielles des supraconducteurs et le dévelopment des théories de la supraconductivité sont esquissés avant de présenter brièvement la découverte des supraconducteurs à base de fer et de donner un aperçu des questions actuelles de recherche dans ce domaine.Dans le chapitre 2, la procédure de croissance de monocristaux de Ba$_{1-x}$K$_x$Fe$_2$As$_2$ par la méthode de "self-flux", leur caractérisation par diffraction et par l'analyse de dispersion d'énergie des rayons X et la sensibilité des mesures de résistivité et de susceptibilité AC sont décrites. Puis nous présentons quelques résultats des mesures de la résistivité dépendante de la température de monocristaux du composé Ba$_{1-x}$K$_x$Fe$_2$As$_2$ (0,23 $\leq x \leq$ 0,4) sous champs magnétiques allant jusqu'à 9 T et dépendante de l'angle.Dans le chapitre 3, nous exposons quelques points essentiels du système de mesure à base de sonde de Hall que nous avons construit. Ensuite, nous présentons des mesures d'aimantation locale et globale sur des polycristaux de SmFeAsO$_{0.9}$F$_{0.1}$ synthétisés à haute pression, et de monocristaux de Ba$_{0.6}$K$_{0.4}$Fe$_2$As$_2$ effectuées par sonde de Hall et VSM.Dans le chapitre 4, nous donnons une brève introduction à la spectroscopie d'Andreev en mode point-contact, puis nous appliquons cette technique à des monocristaux de Ba$_{0.6}$K$_{0.4}$Fe$_2$As$_2$ et à une série de monocristaux de BaFe$_{2-x}$Ni$_x$As$_2$ couvrant une large gamme de dopage.Dans le chapitre 5, le développement d'un microscope de force à nano-SQUID et les mesures effectuées sur un film Rhénium d'épaisseur de 80 nm sont présentés. Le microscope peut acquérir des images topographiques et magnétiques simultanément. La plage de balayage maximale à 0.8 K est de \unit{70} {\micro\meter} $\times$ \unit{85}{\micro\meter} et sa résolution magnétique est d'environ $1,5 \times10^{-4}\Phi_0/\sqrt{\textrm{Hz}}$. Dans le chapitre 6, nous présentons quelques résultats des mesures de $\lambda$ par imagerie par microscopie de force à nano-squid sur des monocristaux de Ba(Fe$_{1-x}$Ni$_x$)$_2$As$_2$, couvrant tout le diagramme de phase. Sur les m\^{e}mes cristaux ont été effectuées des mesures du premier champ critique, de la variation de fréquence d'un oscillateur à diode tunnel et de la capacité calorifique.Enfin, au chapitre 7, un résumé détaillé et critique est présenté. / More than twenty years after the discovery of high temperature superconductors, the underlying physical mechanism is still not well understood. In 2008, the discovery of a new family of high temperature superconductors, the iron-based superconductors, provided us a new chance to understand the high temperature superconductivity. Synthesizing high quality sample, detecting the basic superconducting properties, the gap structure and order parameter symmetry are essential steps in revealing the mechanism and application of new superconductors. This dissertation describes the growth of Ba$_{1-x}$K$_x$Fe$_2$As$_2$ single crystals and the study of superconducting properties, gap structure and order parameter on Ba-122 iron-based superconductors with resistivity, Hall probe, point contact Andreev reflection spectroscopy and scanning nano-squid microscopy measurements. Some historical events concerning superconductivity are recalled, and some key properties and theories of superconductivity are presented in Chapter 1. Then we will briefly introduce the discovery and current research situation of the iron-based superconductors. In Chapter 2, the growth procedure of Ba$_{1-x}$K$_x$Fe$_2$As$_2$ single crystals with self-flux method, and the characterization of the crystals with diffraction and energy dispersive analysis of x-ray, AC susceptibility and resistivity measurements are described. Then we report some results from temperature dependent resistivity measurements on Ba$_{1-x}$K$_x$Fe$_2$As$_2$ (0.23 $\leq x \leq$ 0.4) single crystals in magnetic fields up to 9 T and angle dependent resistivity measurements on Ba$_{0.6}$K$_{0.4}$Fe$_2$As$_2$ single crystals. In Chapter 3, we introduce some details about a Hall probe measurement system we built. Then we present local and global magnetization measurements on high pressure SmFeAsO$_{0.9}$F$_{0.1}$ polycrystals and Ba$_{0.6}$K$_{0.4}$Fe$_2$As$_2$ single crystals with Hall probe and VSM.In Chapter 4, we give a brief introduction about point contact Andreev reflection spectroscopy, then we report the measurements on Ba$_{0.6}$K$_{0.4}$Fe$_2$As$_2$ single crystal and a series of electron-doped BaFe$_{2-x}$Ni$_x$As$_2$ single crystals over a wide doping range.In Chapter 5, the development of a scanning nano-SQUID force microscope and measurements performed on a 80 nm Rhenium film are presented. The microscope can take topographic and magnetic images simultaneously. The maximal scanning range is \unit{70}{\micro\meter} $\times$ \unit{85}{\micro\meter} and the magnetic resolution is about $1.5 \times10^{-4}\Phi_0/\sqrt{\textrm{Hz}}$. In Chapter 6, we present some results from lower critical field, tunnel diode oscillator, heat capacity and scanning nano-squid microscopy measurements on systematic doped Ba(Fe$_{1-x}$Ni$_x$)$_2$As$_2$ single crystals..Finally, in Chapter 7, a detailed summary is presented.
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Electronic phase diagrams and competing ground states of complex iron pnictides and chalcogenides: A Mössbauer spectroscopy and muon spin rotation/relaxation studyKamusella, Sirko 01 March 2017 (has links)
In this thesis the superconducting and magnetic phases of LiOH(Fe,Co)(Se,S), CuFeAs/CuFeSb, and LaFeP_1-xAs_xO - belonging to the 11, 111 and 1111 structural classes of iron-based arsenides and chalcogenides - are investigated by means of 57Fe Mössbauer spectroscopy and muon spin rotation/relaxation (μSR). Of major importance in this study is the application of high magnetic fields in Mössbauer spectroscopy to distinguish and characterize ferro- (FM) and antiferromagnetic (AFM) order. A user-friendly Mössbauer data analysis program was developed to provide suitable model functions not only for high field spectra, but relaxation spectra or parameter distributions in general.
In LaFeP_1-xAs_xO the reconstruction of the Fermi surface is described by the vanishing of the Γ hole pocket with decreasing x. The continuous change of the orbital character and the covalency of the d-electrons is shown by Mössbauer spectroscopy. A novel antiferromagnetic phase with small magnetic moments of ~ 0.1 μ_B state is characterized. The superconducting order parameter is proven to continuously change from a nodal to a fully gapped s-wave like Fermi surface in the superconducting regime as a function of x, partially investigated on (O,F) substituted samples.
LiOHFeSe is one of the novel intercalated FeSe compounds, showing strongly increased T_C = 43 K mainly due to increased interlayer spacing and resulting two-dimensionality of the Fermi surface. The primary interest of the samples of this thesis is the simultaneously observed ferromagnetism and superconductivity. The local probe techniques prove that superconducting sample volume gets replaced by ferromagnetic volume. Ferromagnetism arises from magnetic order with T_C = 10 K of secondary iron in the interlayer. The tendency of this system to show (Li,Fe) disorder is preserved upon (Se,S) substitution. However, superconductivity gets suppressed. The results of Mössbauer spectroscopy indicate that the systems tends to a secondary structural phase, where the local iron environment observed in pure FeS is absent. Moreover, two interlayer positions of the iron are identified. The absence of enhanced superconducting T_C in LiOHFeS thus is related to a structural instability.
Also, in CuFeAs the role of secondary iron at the Cu position turns out to be decisive for the observed magnetic behaviour. As in LiOHFeSe, it orders ferromagnetically at T_C ~ 11 K and superimposes with the magnetic instability of the main iron site. It is shown that a small charge doping of 0.1e/Fe, which is expected from (Cu,Fe) disorder, is sufficient to switch the system between a paramagnetic and an AFM ground state. Both magnetic orders are indistinguishable, because the magnetic order parameters are strongly coupled. This coupling was observed in the structurally identical CuFeSb, where the magnetic order parameters of both iron sites scale perfectly. The magnetically unstable CuFeAs and the ferromagnetic CuFeSb can be classified according to the theory of As height driven magnetism, predicting a change from paramagnetism to AFM and finally FM with increasing As height.:1 Acronyms and Symbols
2 Introduction
3 Iron-based arsenides and chalcogenides
3.1 Structural properties
3.2 Electronic properties
3.2.1 Magnetism
3.2.2 Superconductivity
3.2.3 Nematic phase
3.3 Investigated samples
4 Moessfit - a free Mössbauer fitting program
4.1 Aspects of program design
4.2 Errors
4.2.1 Uncorrelated
4.2.2 Hesse
4.2.3 MonteCarlo
4.2.4 Minos
4.3 Fitting algorithm
4.4 Maximum entropy method (MEM)
4.5 Kolmogorov-Smirnov confidence
5 Mössbauer spectroscopy
5.1 Mössbauer effect
5.2 Relativistic Doppler effect
5.3 Full static Hamiltonian
5.3.1 Quadrupole interaction
5.3.2 Isomer shift.
5.3.3 Zeeman splitting
5.3.4 Combined interaction
5.3.5 Transition probabilities
5.3.6 The magic angle
5.4 Transmission integral
5.4.1 Absorption area
5.4.2 Ideal thickness
5.4.3 Line width and line shape
5.4.4 Levelling
5.5 Applied field measurements of powder samples
5.5.1 Paramagnet, axial symmetric EFG in transverse field geometry 6
5.5.2 Uniaxial antiferromagnet, axial symmetric EFG in transverse field geometry 6
5.5.3 Paramagnet, axial symmetric EFG in longitudinal field geometry 6
5.5.4 Uniaxial ferromagnet, axial symmetric EFG in transverse field geometry 6
5.5.5 Polarised photons
5.5.6 Total absorption cross section
5.5.7 Polarised sources
5.6 Blume line shape model
6 μSR
6.1 Muon decay and detection
6.2 Magnetic order and dynamic relaxation
6.2.1 Magnetic order
6.2.2 Time dependent field distributions
6.2.3 Aspects of μSR in iron-based arsenides and chalcogenides
6.2.4 Weak transverse field (WTF)
6.3 Superconductivity - transverse field (TF) experiments
7 Intercalated FeSe
7.1 Bulk properties: XRD, susceptibility, resistivity
7.2 Structural characterization
7.3 LiOHFeSe - Mössbauer spectroscopy
7.3.1 Applied transverse field
7.4 LiOHFeSe - μSR
7.4.1 Zero field (ZF)
7.4.2 Pinning experiment
7.4.3 Transverse field (TF)
7.5 Mössbauer investigation of LiOHFe_1-yCo_ySe_1-xS_x.
7.6 Discussion
8 LaFeO(As,P)
8.1 Preliminary measurements and electronic structure calculations
8.2 Mössbauer spectroscopy
8.3 μSR
8.3.1 Magnetic characterization
8.3.2 Spin dynamics
8.3.3 Superconductivity
8.4 Discussion
9 CuFeAs and CuFeSb
9.1 Preliminary results of CuFeAs and CuFeSb
9.2 CuFeAs: Mössbauer spectroscopy
9.2.1 Zero field (ZF)
9.2.2 Longitudinal field (LF)
9.2.3 Transverse field (TF)
9.3 CuFeAs: μSR
9.3.1 Zero field (ZF)
9.3.2 Weak transverse field (WTF)
9.4 Further investigations on CuFeAs
9.4.1 Neutron scattering
9.4.2 Theoretical calculation
9.4.3 Local element analysis with EDX/WDX
9.5 CuFeSb: Mössbauer spectroscopy
9.5.1 Zero Field (ZF)
9.5.2 Transverse field (TF)
9.6 Discussion
10 Conclusion
11 Appendix
11.1 Derivation of the quadrupole interaction and isomer shift
11.2 Matrix form of the static nuclear Hamiltonian
11.3 Mössbauer line intensities
11.4 Blume line shape model
11.4.1 Special case: two states with diagonal Hamiltonians
11.5 Moessfit models
11.5.1 FeSe_1-xS_x(Li_1-zFe_zOH) ZF, standard
11.5.2 FeSe_1-xS_x(Li_1-zFe_zOH) ZF, 4 fractions
11.5.3 FeSe_1-xS_x(Li_1-zFe_zOH) Pinning
11.5.4 FeSe_1-xS_x(Li_1-zFe_zOH) TF
11.5.5 FeSe_1-xS_x(Li_1-zFe_zOH) CS-Vzz-MEM
11.5.6 LaFeP_1-xAs_x+ ferrocene, ZF
11.5.7 LaFeP_1-xAs_x+ ferrocene, LF
11.5.8 LaFeP_1-xAs_x+ iron foil, ZF
11.5.9 LaFeAsO ZF
11.5.10 LaFeAsO TF
11.5.11 CuFeAs + ferrocen, ZF
11.5.12 CuFeAs + ferrocen, ZF, high statistics
11.5.13 CuFeAs + ferrocen, LF
11.5.14 CuFeAs + ferrocen, TF
11.5.15 CuFeSb ZF
11.5.16 CuFeSb TF
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