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
Identifer | oai:union.ndltd.org:DRESDEN/oai:qucosa:de:qucosa:30237 |
Date | 01 March 2017 |
Creators | Kamusella, Sirko |
Contributors | Klauß, Hans-Henning, Ksenofontov, Vadim, Technische Universität Dresden |
Source Sets | Hochschulschriftenserver (HSSS) der SLUB Dresden |
Language | English |
Detected Language | English |
Type | doc-type:doctoralThesis, info:eu-repo/semantics/doctoralThesis, doc-type:Text |
Rights | info:eu-repo/semantics/openAccess |
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