Conductivity behavior of LaNiO3- and LaMnO3- based thin film superlattices

Wei, Haoming

09 May 2017

The present work covers the fabrication and electrical and magnetic investigation of LaNiO3- and LaMnO3- based superlattices (SL). In recent years, several interesting theoretical predictions have been made in these SLs, for example, Mott insulators, metal-insulator transitions, superconductivity, topological insulators, and Chern insulators. Motivated by the promising theoretical predictions, four kinds of SLs with different designed structures and orientations were systematically studied in this thesis. The samples were grown by pulsed laser deposition with in-situ reflection high-energy electron diffraction to monitor the two-dimensional layer-by-layer growth process. In order to ensure the high-quality of SLs, growth parameters were optimised. Characteristic methods like X-ray diffraction, atomic force microscopy, and transmission electron microscopy were used. These measurements proved the high-quality of the SLs and provided the basis for electrical and magnetic measurements. The first studied SL is the (001)-oriented LaNiO3/LaAlO3 SL, which was predicted as a superconductor in theory. Temperature-dependent resistivity measurements revealed a metal-insulator transition by lowering the dimensionality of the LaNiO3 layers in the SLs from three dimensions to two dimensions. The second studied SL is the (111)-oriented LaNiO3/LaAlO3 SL, which was predicted as a topological insulator in theory. The polarity-controlled conductivity was observed and the intrinsic conductivity mechanisms were discussed by means of appropriate modeling. The third studied SL is LaMnO3/LaAlO3 SL, which was predicted as a Chern insulator in theory. By lowering the temperature, a paramagnetic-ferromagnetic phase transition and a thermal activated behavior were observed in the SLs. The last studied SL is the LaNiO3/LaMnO3 SL, in which an exchange bias effect was expected. The studies reveal the exchange bias exists in three kinds of SLs with different orientations.

Übergitter

Supraleitung

Topologische Isolatoren

superlattices

chern insulator

superconductivity

exchange bias effect

ddc:530

Untersuchungen zu Gasphasentransporten in quasibinären Systemen von Bi2Se3 mit Bi2Te3, Sb2Se3, MnSe und FeSe zur Erzeugung von Nanokristallen

Nowka, Christian

16 January 2017

In Topologischen Isolatoren (TI) werden metallische Zustände an der Oberfläche beobachtet, während die entsprechenden Volumenzustände eine Bandlücke aufweisen. Der Volumenbeitrag zur Leitfähigkeit von TI-Materialien macht eine Synthese von Nanokristallen bzw. eine Dotierung nötig. Der Fokus der Untersuchungen dieser Arbeit liegt dabei auf der Erzeugung von Nanokristallen der TI-Materialien Bi2Te3- und Bi2Te2Se sowie dotierter Bi2Se3-Nanokristallen. Die Synthese der Nanokristalle erfolgte durch den Gasphasentransport im geschlossenen System über den Mechanismus einer Zersetzungssublimation bzw. unter dem Einsatz eines Transportmittels. Für eine erfolgreiche Erzeugung der Nanokristalle sind im Vorfeld thermodynamische Modellierungen des Gasphasentransports sowie Versuche zum chemischen Transport für die quasibinären Systeme Bi2Se3-Bi2Te3, Bi2Se3-Sb2Se3 und Bi2Se3-FeSe sowie für das ternäre System Mn-Bi-Se durchgeführt worden. Durch Versuche zum chemischen Transport konnten die Aussagen der Modellierung bestätigt und im Weiteren der Dotandengehalt in den abgeschiedenen Kristallen sowie der Einlagerungsmechanismus durch Ergebnisse aus XRD- und ICP-OES-Untersuchungen beschrieben werden. Die Synthese bzw. Dotierung der Nanokristalle wurde hauptsächlich durch die Transportrate und den Dampfdruck des Dotanden bestimmt. In den Systemen Bi2Se3-Bi2Te3 und Bi2Se3-Sb2Se3 ist ein Gasphasentransport über eine Zersetzungssublimation durchführbar und resultierte in einer erfolgreichen Darstellung von Bi2Te3- und Bi2Te2Se-Nanokristallen sowie von dotierten (SbxBi1-x)2Se3-Nanokristallen. Entgegen dessen erfolgte der Gasphasentransport in den Systemen Bi2Se3-FeSe und Mn-Bi-Se unter Verwendung eines Transportmittels. Hierbei verringerten die gesteigerten Transportraten das Wachtum von Nanokristallen. Im Weiteren gelang es dotierte (Fe,Mn)xBi2-xSe3-Volumenkristalle sowie MnBi2Se4-Einkristalle darzustellen und mittels XRD, ICP-OES, magnetischer Messungen sowie elektrischem Transport zu charakterisieren.

Chemischer Transport

Topologische Isolatoren

Bi2Se3

chemical vapor transport

topological insulators

Bi2Se3

ddc:540

rvk:VE 5907

Conductivity behavior of LaNiO3- and LaMnO3- based thin film superlattices

Wei, Haoming

24 April 2017

The present work covers the fabrication and electrical and magnetic investigation of LaNiO3- and LaMnO3- based superlattices (SL). In recent years, several interesting theoretical predictions have been made in these SLs, for example, Mott insulators, metal-insulator transitions, superconductivity, topological insulators, and Chern insulators. Motivated by the promising theoretical predictions, four kinds of SLs with different designed structures and orientations were systematically studied in this thesis. The samples were grown by pulsed laser deposition with in-situ reflection high-energy electron diffraction to monitor the two-dimensional layer-by-layer growth process. In order to ensure the high-quality of SLs, growth parameters were optimised. Characteristic methods like X-ray diffraction, atomic force microscopy, and transmission electron microscopy were used. These measurements proved the high-quality of the SLs and provided the basis for electrical and magnetic measurements. The first studied SL is the (001)-oriented LaNiO3/LaAlO3 SL, which was predicted as a superconductor in theory. Temperature-dependent resistivity measurements revealed a metal-insulator transition by lowering the dimensionality of the LaNiO3 layers in the SLs from three dimensions to two dimensions. The second studied SL is the (111)-oriented LaNiO3/LaAlO3 SL, which was predicted as a topological insulator in theory. The polarity-controlled conductivity was observed and the intrinsic conductivity mechanisms were discussed by means of appropriate modeling. The third studied SL is LaMnO3/LaAlO3 SL, which was predicted as a Chern insulator in theory. By lowering the temperature, a paramagnetic-ferromagnetic phase transition and a thermal activated behavior were observed in the SLs. The last studied SL is the LaNiO3/LaMnO3 SL, in which an exchange bias effect was expected. The studies reveal the exchange bias exists in three kinds of SLs with different orientations.

info:eu-repo/classification/ddc/530

ddc:530

Untersuchungen zu Gasphasentransporten in quasibinären Systemen von Bi2Se3 mit Bi2Te3, Sb2Se3, MnSe und FeSe zur Erzeugung von Nanokristallen

Nowka, Christian

19 December 2016

In Topologischen Isolatoren (TI) werden metallische Zustände an der Oberfläche beobachtet, während die entsprechenden Volumenzustände eine Bandlücke aufweisen. Der Volumenbeitrag zur Leitfähigkeit von TI-Materialien macht eine Synthese von Nanokristallen bzw. eine Dotierung nötig. Der Fokus der Untersuchungen dieser Arbeit liegt dabei auf der Erzeugung von Nanokristallen der TI-Materialien Bi2Te3- und Bi2Te2Se sowie dotierter Bi2Se3-Nanokristallen. Die Synthese der Nanokristalle erfolgte durch den Gasphasentransport im geschlossenen System über den Mechanismus einer Zersetzungssublimation bzw. unter dem Einsatz eines Transportmittels. Für eine erfolgreiche Erzeugung der Nanokristalle sind im Vorfeld thermodynamische Modellierungen des Gasphasentransports sowie Versuche zum chemischen Transport für die quasibinären Systeme Bi2Se3-Bi2Te3, Bi2Se3-Sb2Se3 und Bi2Se3-FeSe sowie für das ternäre System Mn-Bi-Se durchgeführt worden. Durch Versuche zum chemischen Transport konnten die Aussagen der Modellierung bestätigt und im Weiteren der Dotandengehalt in den abgeschiedenen Kristallen sowie der Einlagerungsmechanismus durch Ergebnisse aus XRD- und ICP-OES-Untersuchungen beschrieben werden. Die Synthese bzw. Dotierung der Nanokristalle wurde hauptsächlich durch die Transportrate und den Dampfdruck des Dotanden bestimmt. In den Systemen Bi2Se3-Bi2Te3 und Bi2Se3-Sb2Se3 ist ein Gasphasentransport über eine Zersetzungssublimation durchführbar und resultierte in einer erfolgreichen Darstellung von Bi2Te3- und Bi2Te2Se-Nanokristallen sowie von dotierten (SbxBi1-x)2Se3-Nanokristallen. Entgegen dessen erfolgte der Gasphasentransport in den Systemen Bi2Se3-FeSe und Mn-Bi-Se unter Verwendung eines Transportmittels. Hierbei verringerten die gesteigerten Transportraten das Wachtum von Nanokristallen. Im Weiteren gelang es dotierte (Fe,Mn)xBi2-xSe3-Volumenkristalle sowie MnBi2Se4-Einkristalle darzustellen und mittels XRD, ICP-OES, magnetischer Messungen sowie elektrischem Transport zu charakterisieren.

info:eu-repo/classification/ddc/540

ddc:540

Heat transport in strongly anharmonic solids from first principles

Knoop, Florian

27 April 2022

In dieser Arbeit beschreiben wir wie nicht-störungstheoretischer Wärmetransport im Rahmen von ab initio-Simulationen und linearer Antworttheorie formuliert werden kann. Die daraus resultierende ab initio-Green-Kubo-Methode ermöglicht die Simulation von Wärmetransport in Festkörpern beliebiger Anharmonizität und ist besonders geeignet um "stark anharmonische" Systeme zu beschreiben in denen störungstheoretische Ansätze unzuverlässig werden. Um die systematische Unterscheidung von harmonischen und anharmonischen Materialien zu ermöglichen führen wir ein "Anharmonizitätsmaß" ein, welches die anharmonischen Beiträge zu den interatomaren Kräften unter thermodynamischen Bedingungen quantifiziert. Mit diesem Anharmonizitätsmaß untersuchen wir typische dynamische Effekte die in stark anharmonischen Materialien auftreten, sowie die Grenzen störungstheoretischer Methoden zur Berechnung von Wärmetransporteigenschaften. Wir zeigen, dass eine negative Korrelation des Anharmonizitätsmaßes mit der Wärmeleitfähigkeit einfacher Kristalle besteht, was die intuitive Auffassung bestärkt, wonach harmonische Materialien bessere Wärmeleiter sind und umgekehrt. Auf diesen Erkenntnissen aufbauend identifizieren wird anharmonische Materialien als Kandidaten für Wärmetransport-Simulationen auf der Suche nach neuen thermischen Isolatoren. Auf diesem Wege identifizieren wir mehrere neue thermische Isolatoren welche potentielle technologische Relevanz als thermische Barrieren oder Thermoelektrika aufweisen könnten, und schlagen diese zur experimentellen Untersuchung vor. / In this work, we describe how a non-perturbative heat transport formalism for solids emerges in the framework of ab initio simulations coupled with linear response theory. The resulting ab initio Green Kubo method allows for studying heat transport in solids of arbitrary anharmonic strength, and is particularly suited to describe “strongly anharmonic” systems where per- turbative approaches become unreliable. In order to discern harmonic from anharmonic materials in a systematic way, we introduce an “anharmonicity measure” which quantifies the anharmonic contribution to the interatomic forces under thermodynamic conditions. Using this anharmonicity measure, we investigate typical dynamical effects occurring in strongly anharmonic compounds and investigate the limits of perturbative approaches for the study of thermal transport. We show that this measure negatively correlates with bulk thermal conductivities in simple solids, supporting the intuitive notion that more harmonic materials are better heat conductors and vice versa. Based on these findings, we identify anharmonic compounds as candidates for thermal transport simulations in the search for novel thermal insulators. In this way, we identify several new thermal insulators of potential technological relevance as thermal barriers or thermoelectric materials which we suggest for experimental study.

Physik

Wärmetransport

Dichtefunktionaltheorie

Halbleiter

Isolatoren

physics

heat transport

density functional theory

semiconductors

insulators

530 Physik

ddc:530

A Heavy Graphene Analogue amongst the Bismuth Subiodides as Host for Unusual Physical Phenomena

Rasche, Bertold

16 January 2017

This thesis was inspired by the discovery of Bi14Rh3I9, the first so-called weak three-dimensional topological insulator (3D-TI) and has been concerned with the topic of TIs in general. Two aspects were tackled to gain a deeper understanding of this new state of matter. On one hand, the expansion of the material’s basis and on the other hand developing a simple model of the structure and analysing it via density-functional theory (DFT) based methods. To discover new materials, a systematic investigation of the metal-rich parts of the bismuth–platinum-metal–iodine phase systems was conducted. It led to six new phases among the bismuth subiodides. Some of which, e.g. Bi14Rh3I9, share a honeycomb network of platinum-metal-centred bismuth-cubes and are the seed of a family of materials with this structural motive. The others show strand-like structures or layered structures with platinum-platinum bonds. The latter were so far unknown amongst bismuth subiodides. The honeycomb network was separately analysed and shown to host the TI properties. Structurally and electronically it can be seen as a “heavy graphene analogue”, which refers to the fact that graphene with hypothetical strong spin-orbit coupling (“heavy graphene”) was the first TI put forward by theoreticians. Apart from DFT-calculations, physical experiments confirmed the TI properties. Angle-resolved photoelectron spectroscopy (ARPES) was used to verify the electronic structure and scanning tunnelling microscopy and spectroscopy (STM and STS) to reveal the protected 1D edge states present at the cleaving surface of this material. As the arrangement of the honeycomb layer varies between the different known and newly discovered materials within this family of structures, this influence was also investigated. All further materials were also characterised by DFT-calculations and physical experiments, e.g. magnetisation and transport measurements. This thesis might give an experimental and theoretical basis for a deeper understanding of the TI state of matter. The 1D edge states on the surface of Bi14Rh3I9 could be a chance to handle spins and therefore propel spintronic research, or they could host Majorana fermions, which could be used as qubits in quantum computing.

topologische Isolatoren

Bismutsubiodide

Schichtstrukturen

Bismut

Platin-Metalle

Platin

Rhodium

Palladium

topological insulators

bismuth subiodides

layered structures

bismuth

platinum-metals

platinum

rhodium

palladium

ddc:540

rvk:VE 9407

In situ studies of Bi2Te3 thin films and interfaces grown by molecular beam epitaxy

Mota Pereira, Vanda Marisa

14 March 2022

Three-dimensional topological insulators (TIs) are a class of materials for which the bulk is insulating, while the surface is necessarily metallic. A band inversion that occurs in the presence of spin-orbit coupling, and conduction and valence bands with opposite parities are necessary conditions for the existence of this class of materials. The metallicity of the surface states appears as a consequence of the topology of the bulk and these states are characterized by massless Dirac dispersions and helical spin polarization that protect the surface states against backscattering. The robustness of the topological surface states further implies that they are not destroyed by non-magnetic impurities or defects. Since their initial conception, a vast amount of theoretical studies have predicted very interesting features stemming from the topological surface states. An example of that can be found when breaking the time-reversal symmetry by introducing magnetic order in the system, which can lead to exotic phenomena such as the quantum anomalous Hall effect. The properties exhibited by these systems are expected to be of high importance both in fundamental research as well as in technological applications. However, the major difficulty remains the access to purely topological surface states. The remaining bulk conductivity of the TIs such as Bi2Se3, Bi2Te3 or Sb2Te3 still hinders the experimental realization of some of the predicted phenomena. This highlights the need of high-quality bulk-insulating materials with ultra-clean surfaces and interfaces, which can only be achieved with delicate sample preparation and characterization methods. The present work is part of the effort to fabricate high-quality TI films in a controlled manner. This shall then allow more complex investigations, such as interface effects and possibilities to engineer the band structure of the TIs. The former will be explored mainly in the form of heterostructures of Bi2Te3 and magnetic insulating layers, whereas the latter will focus on the fabrication of Sb2Te3/Bi2Te3 heterostructures. Most of the important properties of the samples are measured under ultra-high vacuum conditions, ensuring reliable results. Furthermore, in situ capping with ordered Te also allows for more sophisticated ex situ experiments. In a first step, the optimization of Bi2Te3 thin films grown on Al2O3 (0001) substrates was explored. Spectroscopic and structural characterization measurements showed that it is possible to obtain consistently bulk-insulating TI films with good structural quality, despite the lattice mismatch between Bi2Te3 and Al2O3 (0001). Magnetoconductance measurements showed a prominent weak anti-localization effect, confirming the existence of two-dimensional surface states. In order to explore the consequences of breaking the time-reversal symmetry characteristic of TIs, Bi2Te3 was interfaced with several ferro- or ferrimagnetic insulating (FI) layers in heterostructures. EuO, Fe3O4, Y3Fe5O12 and Tm3Fe5O12 were chosen as possible candidates. Systematic optimization and characterization studies showed that interfaces of Bi2Te3 and EuO, as well as Fe3O4 on top of Bi2Te3, yield poor quality samples with significant chemical reactions between the layers. Nevertheless, high-quality Bi2Te3 could be grown on Fe3O4 (001), Fe3O4 (111), Y3Fe5O12 (111) and Tm3Fe5O12 (111). Clean interfaces and intact top topological surface states were confirmed by photoemission spectroscopy. Moreover, transport signatures of a gap opening in the topological surface states were found, namely a suppression of the weak anti-localization effect and the observation of the anomalous Hall effect. However, x-ray circular magnetic dichroism (XMCD) was not observed for any of the heterostructures. A key conclusion from this study is that the ferromagnetism induced by the magnetic proximity effect is too weak to be detected by XMCD. On hindsight, one can infer that the magnetic proximity effect cannot be strong since the bonding between the TI and the magnetic insulator substrate is of the van der Waals type, and not covalent like in transition metal oxides or metallic heterostructures. It is known that a charge compensation between electron- and hole-doping can be achieved when combining Bi2Te3 and Sb2Te3, which can also tune the position of the Dirac point. With this goal in mind, the fabrication of ternary (Bi(x)Sb(1−x))2Te3 compounds and Sb2Te3/Bi2Te3 heterostructures was explored in the next step. Although pure Sb2Te3 and (Bi(x)Sb(1−x))2Te3 did not yield good quality samples, the fabrication of Sb2Te3/Bi2Te3 heterostructures emerged as a promising alternative route. Photoelectron spectroscopy allowed not only to identify the crucial role of the first few Sb2Te3 top layers, which modulate the topological surface states, but also to characterize the intermixing of the TI layers at the interface. In a final study, Fe(1+y)Te thin films were grown on MgO (001) substrates employing a Te-limited growth method. This allowed to obtain nominally stoichiometric films, as evidenced by reflection high-energy electron diffraction, x-ray absorption spectroscopy, XMCD and x-ray diffraction measurements. This preliminary study opens the way for the investigation of TI/superconductor interfaces and to delve into the topological superconductivity arising from the proximity effect.

info:eu-repo/classification/ddc/530

ddc:530

Quantum transport investigations of low-dimensional electron gases in AlxGa1-xAs/GaAs- and Bi2Se3-based materials

Riha, Christian

30 August 2019

Die Transporteigenschaften eines Elektronengases mit reduzierter Dimensionalität werden von den Welleneigenschaften der Elektronen bestimmt. Dies ermöglicht es, verschiedene Quanteneffekte, wie Quanteninterferenz, zu beobachten. Im ersten Teil dieser Arbeit werden geätzte Quantenringe und eindimensionale (1D) Verengungen, basierend auf AlxGa1-xAs/GaAs-Heterostrukturen, hinsichtlich ihrer Transporteigenschaften untersucht. Messungen des thermischen Rauschens im Gleichgewichtszustand zeigen, dass der Erwartungswert mit den Rauschspektren aller 1D Verengungen übereinstimmt, jedoch um bis zu 60 % bei allen Quantenringen überschritten wird. Rauschmessungen im thermischen Nichtgleichgewicht ergeben, dass der Wärmefluss in Quantenringen mithilfe einer globalen Steuerelektrode (Topgate) an- und ausgeschaltet werden kann. Die magnetische Widerstandsänderung der Quantenringe zeigt Oszillationen, die dem Aharonov-Bohm-Effekt zugeordnet werden. Die Beobachtbarkeit dieser Oszillationen hängt stark von dem Abkühlvorgang der Probe ab und die Oszillationen zeigen Hinweise auf ein Schwebungsmuster sowie auf Phasenstarre. Im zweiten Teil der Arbeit werden die Oberflächenzustände von exfolierten Bi2Se3 Mikroflocken untersucht. Für Mikroflocken mit metallischen Temperaturabhängigkeiten des Widerstandes wurde schwache Anti-Lokalisierung beobachtet. Diese Beobachtung deutet darauf hin, dass sich die magnetische Widerstandsänderung weniger ausschließlich aus den 2D Oberflächenkanälen als vielmehr aus einem geschichtetem Transport von 2D Kanälen im Volumenkörper zusammensetzt. Eine Mikroflocke mit halbleitenden Eigenschaften zeigt keine Hinweise auf solch einen geschichteten 2D Transport und es wird angenommen, dass ihre magnetische Widerstandsänderung ausschließlich von den 2D Oberflächenzuständen verursacht wird. / The transport properties of an electron gas with reduced dimensionality are dominated by the electron’s wave nature. This allows to observe various quantum effects, such as quantum interference. In the first part of this thesis etched quantum rings and one-dimensional (1D) constrictions, based on AlxGa1-xAs/GaAs heterostructures, are investigated with respect to their transport properties. Thermal noise measurements in equilibrium show that the expectation value agrees with the noise spectra of all 1D constrictions but is exceeded by up to 60 % for the noise spectra of all quantum rings. Noise measurements in thermal non-equilibrium reveal that the heat flow can be switched on and off for a quantum ring by a global top-gate. The measured magnetoresistance of the quantum rings shows oscillations that are attributed to the Aharonov-Bohm effect. The observability of these oscillations strongly depends on the cooling process of the sample and the oscillations show indications of a beating as well as phase rigidity. In the second part of the thesis the surface states of exfoliated Bi2Se3 microflakes are studied. For microflakes that show a metallic temperature dependence of the resistance weak anti-localization is observed. This observation suggests that the magnetoresistance is a result of layered transport of 2D channels in the bulk rather than just the surface 2D channels. A microflake with semiconducting characteristics does not show indications of such a 2D layered transport and its magnetoresistance is considered to be carried by the 2D surface states only.

Thermisches Rauschen

Niederdimensionaler Elektronentransport

Quanteninterferenz

Topologische Isolatoren

Thermal noise

Low-dimensional electron transport

Quantum interference

Topological insulators

530 Physik

UP 3150

UP 5050

ddc:530

Tailoring non-classical states of light for applications in quantum information processing

Tschernig, Konrad

26 October 2022

In dieser Arbeit wird das Design und die Präparation von nicht-klassischen Zuständen von Licht in verschiedenen Szenarien untersucht. Zunächst wird die theoretische Beschreibung eines Interferometers entwickelt, welches für die Messung der Teilchenaustauschphase von Photonen entworfen wurde. Die Analyse der experimentellen Daten offenbart den bosonischen Charakter von Photonen, sowie die geometrische Phase, welche mit dem physischen Austausch zweier Quantenzustände assoziiert ist. Nach dieser Feststellung der Austauschsymmetrie von Zweiphotonenzuständen folgt die Ausarbeitung der Theorie über die Propagation von Mehrphotonenzuständen in Multiportsystemen. Dabei offenbaren sich hoch-dimensionale, synthetische, gekoppelte Strukturen die sich aus der Mehrphotonenanregung von diskreten Systemen ergeben. Basierend auf diesen Resultaten wird eine konkrete Anwendung der Theorie im Kontext von nicht-hermitischen Systemen formuliert. Dabei ergeben sich sogenannte “exceptional points” höherer Ordnung, welche Anwendungen im Bereich der Sensorik finden und ferner nur im Raum der Photonenanzahlzustände von diskreten Systemen realisiert werden können. Neben der Sensorik ist der Transport von Lichtzuständen ein wichtiger Aspekt in der Verarbeitung von Quanteninformationen. In dieser Hinsicht werden hier Photonische Topologische Isolatoren untersucht, welche eine rückstreuungsfreie Propagation entlang ihrer Ränder erlauben. Es wird gezeigt, dass partiell kohärentes Licht, Gaussisch und Nicht-Gaussisch verschränkte Zweiphotonenzustände einen solchen topologischen Schutz genießen können. Dies gilt unter der Vorraussetzung, dass die Anfangsanregung in einem wohldefinierten Bereich des topologischen Schutzes liegt, wodurch das “klassische” Bandlücken-kriterium erweitert und gestärkt wird. / In this work we study the design and preparation of non-classical states of light in several scenarios. We begin by developing the theoretical description of an interferometer, which is designed to measure the particle exchange phase of photons. The analysis of the experimental data reveals the bosonic nature of photons, as well as the geometric phase associated with the physical exchange of the quantum states of two photons. Having established the exchange symmetry of two-photon states, we proceed to develop the theory of multi-photon states propagating in multi-port systems. We unveil the high- dimensional synthetic coupled structures that arise via the multi-photon excitation of discrete systems. Using these results, we formulate an application of the theory in the context of non-hermitian systems. We find so-called high-order exceptional points, which find applications in sensing and can only be achieved in the photon-number space of discrete systems. Apart from sensing, an important ingredient for the processing of quantum information is the transport of light states. In this regard, we consider photonic topological insulators, which allow the back-scattering-free propagation along their edges. We show that partially coherent light, Gaussian- as well as non-Gaussian two-photon entangled states can enjoy such a topological protection, provided that the initial excitations fit inside a well defined topological window of protection, which strengthens the “classical” band-gap protection criterion.

Exzeptionelle Punkte

Topologische Isolatoren

Diskrete Quantenoptik

Photonik

Quantenstatistik

Exceptional Points

Topological Insulators

Discrete Quantum Optics

Photonics

Quantum Statistics

530 Physik

ddc:530

Bismuth Subiodides with Chains of Transition Metal-Stabilised Clusters

Herz, Maria Annette

26 February 2024

Topological insulators are a novel class of quantum materials wherein the bulk of the material is an insulator, while the surface or edge states are quantum mechanically protected and conducting. This class of materials offers a lot of promise in the fields of quantum computing and spintronics due to their inherent ability to conduct electrons without the loss of any energy over longer distances, thereby theoretically being able to solve the problems of heat accumulation and leaking of electrons due to tunnelling in current devices. To this end, this work focussed on three main objectives: (a) investigate known bismuth structures as hosts for topological and quantum effects, in particular as potential topological insulators; (b) exploring the possibilities of magnetic substitutions in both known weak 3D topological insulators and further bismuth subhalide structures; and (c) gaining an understanding of the formation processes of the aforementioned substitutions into the bismuth subhalide compounds through extensive thermal analyses. This was realised by investigating Bi2[PtBi6I12]3 and Bi14Rh3I9 as host structures, with the former being a topologically trivial compound and the latter a weak 3D topological insulator. Due to previous difficulties in substituting magnetic cations into Bi14Rh3I9, the initial focus of this work lay in substituting magnetic cations into Bi2[PtBi6I12]3. This work then showed that not only could infinite cluster strands containing the [PtBi6I12]2- clusters be formed with Pb, Sn and Sb in the counter-cation site between them, but that magnetic cations such as Mn, Fe and Co could also be substituted into bismuth subhalide structures. The latter in particular gave rise to novel physical properties in this class of compounds and illuminated and helped explain the previous challenges in substituting magnetic cations into the bismuth subhalides.

info:eu-repo/classification/ddc/540

ddc:540