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Topological insulators are electronic phases that insulate in the bulk and accommodate a peculiar, metallic edge liquid with a spin-dependent dispersion.
They are regarded to be of considerable future use in spintronics and for quantum computation.
Besides determining the intrinsic properties of this rather novel electronic phase, considering its combination with well-known physical systems can generate genuinely new physics.
In this thesis, we report on such combinations including topological insulators. Specifically, we analyze an attached Rashba impurity, a Kondo dot in the two channel setup, magnetic impurities on the surface of a strong three-dimensional topological insulator, the proximity coupling of the latter system to a superconductor, and hybrid systems consisting of a topological insulator and a semimetal.
Let us summarize our primary results.
Firstly, we determine an analytical formula for the Kondo cloud and describe its possible detection in current correlations far away from the Kondo region.
We thereby rely on and extend the method of refermionizable points.
Furthermore, we find a class of gapless topological superconductors and semimetals, which accommodate edge states that behave similarly to the ones of globally gapped topological phases. Unexpectedly, we also find edge states that change their chirality when affected by sufficiently strong disorder.
We regard the presented research helpful in future classifications and applications of systems containing topological insulators, of which we propose some examples.
In the field of spintronics, spin manipulation and spin transport are the main principles that need to be implemented. The main focus of this thesis is to analyse semiconductor systems where high fidelity in these principles can be achieved. To this end, we use numerical methods for precise results, supplemented by simpler analytical models for interpretation.
The material system of 2D topological insulators, HgTe/CdTe quantum wells, is interesting not only because it provides a topologically distinct phase of matter, physically manifested in its protected transport properties, but also since within this system, ballistic transport of high quality can be realized, with Rashba spin-orbit coupling and electron densities that are tunable by electrical gating. Extending the Bernvevig-Hughes-Zhang model for 2D topological insulators, we derive an effective four-band model including Rashba spin-orbit terms due to an applied potential that breaks the spatial inversion symmetry of the quantum well. Spin transport in this system shows interesting physics because the effects of Rashba spin-orbit terms and the intrinsic Dirac-like spin-orbit terms compete. We show that the resulting spin Hall signal can be dominated by the effect of Rashba spin-orbit coupling. Based on spin splitting due to the latter, we propose a beam splitter setup for all-electrical generation and detection of spin currents. Its working principle is similar to optical birefringence. In this setup, we analyse spin current and spin polarization signals of different spin vector components and show that large in-plane spin polarization of the current can be obtained. Since spin is not a conserved quantity of the model,
we first analyse the transport of helicity, a conserved quantity even in presence of Rashba spin-orbit terms. The polarization defined in terms of helicity is related to in-plane polarization of the physical spin.
Further, we analyse thermoelectric transport in a setup showing the spin Hall effect. Due to spin-orbit coupling, an applied temperature gradient generates a transverse spin current, i.e. a spin Nernst effect, which is related to the spin Hall effect by a Mott-like relation. In the metallic energy regimes, the signals are qualitatively explained by simple analytic models. In the insulating regime, we observe a spin Nernst signal that originates from the finite-size induced overlap of edge states.
In the part on methods, we discuss two complementary methods for construction of effective semiconductor models, the envelope function theory and the method of invariants. Further, we present elements of transport theory, with some emphasis on spin-dependent signals. We show the connections of the adiabatic theorem of quantum mechanics to the semiclassical theory of electronic transport and to the characterization of topological phases. Further, as application of the adiabatic theorem to a control problem, we show that universal control of a single spin in a heavy-hole quantum dot is experimentally realizable without breaking time reversal invariance,
but using a quadrupole field which is adiabatically changed as control knob. For experimental realization, we propose a GaAs/GaAlAs quantum well system.
It is generally agreed upon the fact that the Standard Model of particle physics can only be viewed as an effective theory that needs to be extended as it leaves some essential questions unanswered. The exact realization of the necessary extension is subject to discussion. Supersymmetry is among the most promising approaches to physics beyond the Standard Model as it can simultaneously solve the hierarchy problem and provide an explanation for the dark matter abundance in the universe. Despite further virtues like gauge coupling unification and radiative electroweak symmetry breaking, minimal supersymmetric models cannot be the ultimate answer to the open questions of the Standard Model as they still do not incorporate neutrino masses and are besides heavily constrained by LHC data. This does, however, not derogate the beauty of the concept of supersymmetry. It is therefore time to explore non-minimal supersymmetric models which are able to close these gaps, review their consistency, test them against experimental data and provide prospects for future experiments.
The goal of this thesis is to contribute to this process by exploring an extraordinarily well motivated class of models which bases upon a left-right symmetric gauge group. While relaxing the tension with LHC data, those models automatically include the ingredients for neutrino masses.
We start with a left-right supersymmetric model at the TeV scale in which scalar \(SU(2)_R\) triplets are responsible for the breaking of left-right symmetry as well as for the generation of neutrino masses. Although a tachyonic doubly-charged scalar is present at tree-level in this kind of models, we show by performing the first complete one-loop evaluation that it gains a real mass at the loop level. The constraints on the predicted additional charged gauge bosons are then evaluated using LHC data, and we find that we can explain small excesses in the data of which the current LHC run will reveal if they are actual new physics signals or just background fluctuations. In a careful evaluation of the loop-corrected scalar potential we then identify parameter regions in which the vacuum with the phenomenologically correct symmetry-breaking properties is stable. Conveniently, those regions favour low left-right symmetry breaking scales which are accessible at the LHC.
In a slightly modified version of this model where a \(U(1)_R × U(1)_{B−L}\) gauge symmetry survives down to the TeV scale, we implement a minimal gauge-mediated supersymmetry breaking mechanism for which we calculate the boundary conditions in the presence of gauge kinetic mixing. We show how the presence of the extended gauge group raises the tree-level Higgs mass considerably so that the need for heavy supersymmetric spectra is relaxed. Taking the constraints from the Higgs sector into account, we then explore the LHC phenomenology of this model and point out where the expected collider signatures can be distinguished from standard scenarios.
In particular if neutrino masses are explained by low-scale seesaw mechanisms as is done throughout this work, there are potentially spectacular signals at low-energy experiments which search for charged lepton flavour violation. The last part of this thesis is dedicated to the detailed exploration of processes like μ → e γ, μ → 3 e or μ−e conversion in nuclei in a supersymmetric framework with an inverse seesaw mechanism. In particular, we disprove claims about a non-decoupling effect in Z-mediated three-body decays and study the prospects for discovering and distinguishing signals at near-future experiments. In this context we identify the possibility to deduce from ratios like BR(\(τ → 3 μ\))/BR(\(τ → μ e^+ e^−\)) whether the contributions from ν − W loops dominate over supersymmetric contributions or vice versa.
Das Magnetfeld der Sonne ist kein einfaches statisches Dipolfeld, sondern weist
wesentlich kompliziertere Strukturen auf. Wenn Rekonnexion die Topologie eines
Feldlinienbündels verändert, wird viel Energie frei, die zuvor im Magnetfeld
gespeichert war. Das abgetrennte Bündel wird mit dem damit verbundenen Plasma
mit großer Geschwindigkeit durch die Korona
von der Sonne weg bewegen. Dieser Vorgang wird als koronaler Massenauswurf
bezeichnet. Da diese Bewegung mit Geschwindigkeiten deutlich über der
Alfv\'en-Geschwindigkeit, der kritischen Geschwindigkeit im Sonnenwind,
erfolgen kann, bildet sich eine Schockfront, die durch den Sonnenwind
propagiert.
Satelliten, die die Bedingungen im Sonnenwind beobachten, detektieren beim
Auftreten solcher Schockfronten einen erhöhten Fluss von hochenergetischen
Teilchen. Mit Radioinstrumenten empfängt man zeitgleich elektromagnetische
Phänomene, die als Radiobursts bezeichnet werden, und ebenfalls für die
Anwesenheit energiereicher Teilchen sprechen. Daher, und aufgrund von
theoretischen Überlegungen liegt es nahe, anzunehmen, daß Teilchen an der
Schockfront beschleunigt werden können.
Die Untersuchung der Teilchenbeschleunigung an kollisionsfreien Schockfronten
ist aber noch aus einem zweiten Grund interessant. Die Erde wird kontinuierlich
von hochenergetischen Teilchen, die aus historischen Gründen als kosmische
Strahlung bezeichnet werden, erreicht. Die gängige Theorie für deren Herkunft
besagt, daß zumindest der galaktische Anteil durch die Beschleunigung an
Schockfronten, die durch Supernovae ausgelöst wurden, bis zu den beobachteten
hohen Energien gelangt sind. Das Problem bei der Untersuchung der Herkunft der
kosmischen Strahlung ist jedoch, daß die Schockfronten um Supernovaüberreste
aufgrund der großen Entfernung nicht direkt beobachtbar sind.
Es liegt dementsprechend nahe, die Schockbeschleunigung an den wesentlich
näheren und besser zu beobachtenden Schocks im Sonnensystem zu studieren, um so
Modelle und Simulationen entwickeln und testen zu können.
Die vorliegende Arbeit beschäftigt sich daher mit Simulationen von
Schockfronten mit Parametern, die etwa denen von CME getriebenen Schocks
entsprechen. Um die Entwicklung der Energieverteilung der Teilchen zu studieren,
ist ein kinetischer Ansatz nötig. Dementsprechend wurden die Simulationen mit
einem Particle-in-Cell Code durchgeführt. Die Herausforderung ist dabei die
große Spanne zwischen den mikrophysikalischen Zeit- und Längenskalen, die aus
Gründen der Genauigkeit und numerischen Stabilität aufgelöst werden müssen und
den wesentlich größeren Skalen, die die Schockfront umfasst und auf der
Teilchenbeschleunigung stattfindet.
Um die Stabilität und physikalische Aussagekraft der Simulationen
sicherzustellen, werden die numerischen Bausteine mittels Testfällen, deren
Verhalten bekannt ist, gründlich auf ihre Tauglichkeit und korrekte
Implementierung geprüft.
Bei den resultierenden Simulationen wird das Zutreffen von analytischen
Vorhersagen (etwa die Einhaltung der Sprungbedingungen) überprüft. Auch die
Vorhersagen einfacherer Plasmamodelle, etwa für das elektrostatischen
Potential an der Schockfront, das man auch aus einer Zwei-Fluid-Beschreibung
erhalten kann, folgen automatisch aus der selbstkonsistenten, kinetischen
Beschreibung. Zusätzlich erhält man Aussagen über das Spektrum und die Bahnen
der beschleunigten Teilchen.
This thesis deals with quantum Monte Carlo simulations of correlated low dimensional electron systems. The correlation that we have in mind is always given by the Hubbard type electron electron interaction in various settings. To facilitate this task, we develop the necessary methods in the first part. We develop the continuous time interaction expansion quantum algorithm in a manner suitable for the treatment of effective and non-equilibrium problems. In the second part of this thesis we consider various applications of the algorithms. First we examine a correlated one-dimensional chain of electrons that is subject to some form of quench dynamics where we suddenly switch off the Hubbard interaction. We find the light-cone-like Lieb-Robinson bounds and forms of restricted equilibration subject to the conserved quantities. Then we consider a Hubbard chain subject to Rashba spin-orbit coupling in thermal equilibrium. This system could very well be realized on a surface with the help of metallic adatoms. We find that we can analytically connect the given model to a model without spin-orbit coupling. This link enabled us to interpret various results for the standard Hubbard model, such as the single-particle spectra, now in the context of the Hubbard model with Rashba spin-orbit interaction. And finally we have considered a magnetic impurity in a host consisting of a topological insulator. We find that the impurity still exhibits the same features as known from the single impurity Anderson model. Additionally we study the effects of the impurity in the bath and we find that in the parameter regime where the Kondo singlet is formed the edge state of the topological insulator is rerouted around the impurity.
Bis heute ist nicht bekannt, in welcher Umgebung die schwersten Elemente durch Neutroneneinfangprozesse entstehen. Es gibt zwei mögliche Szenarien, die in der Literatur diskutiert werden: Supernova-Explosionen und Neutronensternverschmelzungen. Beide tragen zur Elementproduktion bei. Welches Szenario aber die dominierende Umgebung ist, bleibt umstritten. Mehrere Fakten sprechen für Supernova-Explosionen als Entstehungsorte: Wenn ein massereicher Stern kollabiert und anschließend explodiert, sind die Temperatur und die Dichte so hoch, dass Neutronen von den bereits bestehenden Elementen eingefangen und angelagert werden können. Obwohl in Simulationen mit kugelsymmetrischen Modellen nur protonen- reiche Auswürfe entstehen, kann es in asymmetrischen Explosionen aufgrund der Rotation und der Magnetfelder vermutlich zu einem neutronenreichen Auswurf kommen. Dieser ist hoch genug, dass der schnelle Neutroneneinfang auftreten kann. In dieser Arbeit habe ich daher die Überreste solcher Explosionen untersucht, um nach Asymmetrien und ihren möglichen Auswirkungen auf die Element-Entstehung und Verteilung zu suchen. Dafür wurden die beiden Supernova-Überreste CTB 109 und RCW 103 ausgewählt. CTB 109 besitzt im Zentrum einen anomale Röntgenpulsar, also einen Neutronenstern mit hohem Magnetfeld und starker Rotation, die durch Asymmetrien hervorgerufen worden sein könnten. Auch RCW 103 hat vermutlich einen solchen Pulsar als zentrale Quelle. Beide Überreste sind noch recht jung und befinden sich in ihrer Sedov-Taylor Phase. Die Distanz zur Erde beträgt für beide Überreste ungefähr 3 kpc, womit sie in der näheren Umgebung der Erde zu finden sind. Die Elemente bis zur Eisengruppe haben ihre bekanntesten Linien im Bereich der Röntgenstrahlung. Deswegen wurden für diese Arbeit archivierte Daten des Satelliten XMM-Newton ausgewählt und die Spektren in definierten Regionen in den bei- den Supernova-Überresten mit den EPIC MOS-Kameras ausgewertet. Die heutigen Röntgensatelliten haben jedoch keine ausreichende Sensitivität, um die schwersten Elemente zu detektieren. In den Spektren der beiden Überreste wurden deshalb vorwiegend die Elemente Silizium und Magnesium gefunden, in CTB 109 auch Neon. Elemente mit höheren Massezahlen konnten leider nicht signifikant aus dem Hintergrund herausgefiltert werden. Deutlich sind die Peaks der drei Elementen sichtbar, aber auch Schwefel ist in den Regionen mit hohen Zählraten zu entdecken. Für bei- de Supernova-Überreste wurde der beste Fit mit dem Modell vpshock gefunden. In diesem Modell wird ein Plasma angenommen, das bei konstanter Temperatur plan-parallel geschockt wird. Um diesen Fit zu erzielen wurden die Parameter für die Elemente Fe, S, Si, Mg, O und Ne variiert. Die restlichen Elemente wurden auf die solare Häufigkeit festgelegt. Bei CTB 109 befinden sich die Temperaturen (kT) in den Regionen mit hohen Zählraten im Bereich zwischen 0.6 und 0.7 keV und liegen damit im selben Bereich, der bereits mit anderen Teleskopen für CTB 109 gefunden wurde. In den Regionen mit niedrigen Zählraten liegen die Temperaturen etwas tiefer mit 0.3-0.4 keV. Im Supernova-Überrest RCW 103 wurde nur eine Region mit hoher Zählrate analysiert und eine Temperatur von 0.57 keV gefunden, während in der Region mit niedriger Zählrate die Temperatur kT = 0.36 ± 0.08 keV beträgt. Beide Werte passen zu den Werten in CTB 109. Die einzelnen Elementlinien wurden zusätzlich mit einer Gauß-Verteilung angepasst und die Flüsse ermittelt. Diese wurden in Intensitätskarten aufgetragen, in denen die unterschiedlichen Verteilungen der Elemente über den Supernova-Überrest zu sehen sind. Während Silizium in einigen wenigen Regionen geklumpt auftritt, ist Magnesium über die Überreste verteilt und hat in einigen Regionen höhere Werte als Silizium. Das lässt den Schluss zu, dass die beiden Elemente auf unterschiedliche Weise aus der Explosion herausgeschleudert wurden. Die Verteilung ist hier durchaus asymmetrisch, es ist jedoch nicht möglich dies auf eine asymmetrische Explosion der Supernova zurückzuführen. Dafür müssen mehr als zwei Supernova-Überreste mit dieser Methode untersucht werden und mit einer noch nicht vorhandenen Theorie zur Verteilung der Elemente in Überresten verglichen werden. Im direkten Vergleich der beiden bisher untersuchten Supernova-Überreste CTB 109 und RCW 103 sieht man, dass die beiden Überreste sich sehr in der Temperatur und der Verteilung der Elemente ähneln. Das lässt auf eine einheitliche Ausbreitung der Elemente innerhalb der Supernova-Überreste schließen. Silizium wird aufgrund der Explosion in fingerartigen Strukturen, die Rayleigh-Taylor-Instabilitäten, nach außen transportiert. Dabei bildet es Klumpen, die mit den weiter außen liegenden Schalen reagieren. Magnesium und Neon hingegen werden hauptsächlich in den Brennphasen vor der Explosion und in den äußeren Schichten des Sterns, der Zwiebelschalenstruktur, produziert. Dadurch ist eine ausgedehnte Verteilung zu er- warten. Diese Verteilungen der drei Elemente ist in dieser Arbeit bestätigt worden. Während Magnesium und Neon über den gesamten Überrest hohe Flüsse aufweisen, ist Silizium sehr lokal im Lobe von CTB 109 und im hellen Süden von RCW 103 zu finden. Mit zukünftigen Röntgenteleskopen, die eine höhere räumliche Auflösung ermöglichen, könnten die beobachteten Zusammenhänge zwischen der asymmetrischen Elementverteilung im Supernovaüberrest und den Mechanismen der Elemententstehung in der Supernova weiter untersucht werden.
In this thesis, we investigate aspects of the physics of heavy-fermion systems and correlated topological insulators.
We numerically solve the interacting Hamiltonians that model the physical systems using quantum Monte Carlo algorithms
to access both ground-state and finite-temperature observables.
Initially, we focus on the metamagnetic transition in the Kondo lattice model for heavy fermions.
On the basis of the dynamical mean-field theory and the dynamical cluster approximation,
our calculations point towards a continuous transition, where the signatures of metamagnetism are linked to a Lifshitz transition of heavy-fermion bands.
In the second part of the thesis, we study various aspects of magnetic pi fluxes in the Kane-Mele-Hubbard model of a correlated topological insulator.
We describe a numerical measurement of the topological index, based on the localized mid-gap states that are provided by pi flux insertions.
Furthermore, we take advantage of the intrinsic spin degree of freedom of a pi flux to devise instances of interacting quantum spin systems.
In the third part of the thesis, we introduce and characterize the Kane-Mele-Hubbard model on the pi flux honeycomb lattice.
We place particular emphasis on the correlations effects along the one-dimensional boundary of the lattice and
compare results from a bosonization study with finite-size quantum Monte Carlo simulations.
In the course of the growth of the Internet and due to increasing availability of data, over the last two decades, the field of network science has established itself as an own area of research. With quantitative scientists from computer science, mathematics, and physics working on datasets from biology, economics, sociology, political sciences, and many others, network science serves as a paradigm for interdisciplinary research.
One of the major goals in network science is to unravel the relationship between topological graph structure and a network’s function. As evidence suggests, systems from the same fields, i.e. with similar function, tend to exhibit similar structure. However, it is still vague whether a similar graph structure automatically implies likewise function. This dissertation aims at helping to bridge this gap, while particularly focusing on the role of triadic structures.
After a general introduction to the main concepts of network science, existing work devoted to the relevance of triadic substructures is reviewed. A major challenge in modeling triadic structure is the fact that not all three-node subgraphs can be specified independently
of each other, as pairs of nodes may participate in multiple of those triadic subgraphs.
In order to overcome this obstacle, we suggest a novel class of generative network models based on so called Steiner triple systems. The latter are partitions of a graph’s vertices into pair-disjoint triples (Steiner triples). Thus, the configurations on Steiner triples can be specified independently of each other without overdetermining the network’s link
structure.
Subsequently, we investigate the most basic realization of this new class of models. We call it the triadic random graph model (TRGM). The TRGM is parametrized by a probability distribution over all possible triadic subgraph patterns. In order to generate a network instantiation of the model, for all Steiner triples in the system, a pattern is drawn from the distribution and adjusted randomly on the Steiner triple. We calculate the degree distribution of the TRGM analytically and find it to be similar to a Poissonian distribution. Furthermore, it is shown that TRGMs possess non-trivial triadic structure. We discover inevitable correlations in the abundance of certain triadic subgraph
patterns which should be taken into account when attributing functional relevance to particular motifs – patterns which occur significantly more frequently than expected at random. Beyond, the strong impact of the probability distributions on the Steiner triples on the occurrence of triadic subgraphs over the whole network is demonstrated. This interdependence allows us to design ensembles of networks with predefined triadic substructure. Hence, TRGMs help to overcome the lack of generative models needed for assessing the relevance of triadic structure.
We further investigate whether motifs occur homogeneously or heterogeneously distributed over a graph. Therefore, we study triadic subgraph structures in each node’s neighborhood individually. In order to quantitatively measure structure from an individual node’s perspective, we introduce an algorithm for node-specific pattern mining for both directed unsigned, and undirected signed networks. Analyzing real-world datasets, we find that there are networks in which motifs are distributed highly heterogeneously, bound to the proximity of only very few nodes. Moreover, we observe indication for the potential sensitivity of biological systems to a targeted removal of these critical vertices. In addition, we study whole graphs with respect to the homogeneity and homophily of their node-specific triadic structure. The former describes the similarity of subgraph distributions in the neighborhoods of individual vertices. The latter quantifies whether connected vertices
are structurally more similar than non-connected ones. We discover these features to be characteristic for the networks’ origins. Moreover, clustering the vertices of graphs regarding their triadic structure, we investigate structural groups in the neural network of C. elegans, the international airport-connection network, and the global network of diplomatic sentiments between countries. For the latter we find evidence for the instability of triangles considered socially unbalanced according to sociological theories.
Finally, we utilize our TRGM to explore ensembles of networks with similar triadic substructure in terms of the evolution of dynamical processes acting on their nodes. Focusing on oscillators, coupled along the graphs’ edges, we observe that certain triad motifs impose a clear signature on the systems’ dynamics, even when embedded in a larger
network structure.
In this thesis, the broad band emission, especially in the gamma-ray and radio band, of the active galaxy IC 310 located in the Perseus cluster of galaxies was investigated. The main experimental methods were Cherenkov astronomy using the MAGIC telescopes and high resolution very
long baseline interferometry (VLBI) at radio frequencies (MOJAVE, EVN). Additionally, data
of the object in different energy bands were studied and a multi-wavelength campaign has been
organized and conducted. During the campaign, an exceptional bright gamma-ray flare at TeV
energies was found with the MAGIC telescopes. The results were compared to theoretical acceleration and emission models for explaining the high energy radiation of active galactic nuclei. Many open questions regarding the particle acceleration to very high energies in the jets of active galactic nuclei, the particle content of the jets, or how the jets are launched, were addressed in this thesis by investigating the variability of IC 310 in the very high energy band.
It is argued that IC310 was originally mis-classified as a head-tail radio galaxy. Instead,
it shows a variability behavior in the radio, X-ray, and gamma-ray band similar to the one
found for blazars. These are active galactic nuclei that are characterized by flux variability in all observed energy bands and at all observed time scales. They are viewed at a small angle between the jet axis and the line-of-sight. Thus, strong relativistic beaming influences the variability properties of blazars. Observations of IC 310 with the European VLBI Network helped to find limits for the angle between the jet axis and the line-of-sight, namely 10 deg - 20 deg. This places IC 310 at the borderline between radio galaxies (larger angles) and blazars (smaller angles).
During the gamma-ray outburst detected at the beginning of the multi-wavelength campaign, flux variability as short as minutes was measured. The spectrum during the flare can be described by a simple power-law function over two orders of magnitude in energy up to ~10 TeV. Compared to previous observations, no significant variability of the spectral shape was found. Together with the constraint on the viewing angle, this challenges the currently accepted models for particle acceleration at shock waves in the jets. Alternative models, such as stars moving through the jets, mini-jets in the jet caused, e.g., by reconnection events, or gap acceleration in a pulsar-like magnetosphere around the black hole were investigated. It was found that only the latter can explain all observational findings, which at least suggests that it could even be worthwhile to reconsider published investigations of AGN with this new knowledge in mind.
The first multi-wavelength campaign was successfully been conducted in 2012/2013, including
ground-based as well as space-based telescopes in the radio, optical, ultraviolet, X-ray, and
gamma-ray energy range. No pronounced variability was found after the TeV flare in any energy band. The X-ray data showed a slightly harder spectrum when the emission was brighter. The long-term radio light curve indicated a flickering flux variability, but no strong hint for a
new jet component was found from VLBI images of the radio jet. In any case, further analysis of the existing multi-wavelength data as well as complimentary measurements could provide further exciting insights, e.g., about the broad band spectral energy distribution.
Overall, it can be stated that IC 310 is a key object for research of active galactic nuclei in
the high-energy band due to its proximity and its peculiar properties regarding flux variability
and spectral behavior. Such objects are ideally suited for studying particle acceleration, jet
formation, and other physical effects and models which are far from being fully understood.
It is natural to consider the possibility that the most energetic particles detected (> 10^18 eV), ultra-high-energy cosmic rays (UHECRs), are originated at the most luminous transient events observed (> 10^52 erg s^-1), gamma-ray bursts (GRBs). As a result of the interaction of highly-accelerated, magnetically-confined protons and ions with the photon field inside the burst, both neutrons and UHE neutrinos are expected to be created: the former escape the source and beta-decay into protons which propagate to Earth, where they are detected as UHECRs, while the latter, if detected, would constitute the smoking gun of hadronic acceleration in the sources.
Recently, km-scale neutrino telescopes such as IceCube have finally reached the sensitivities required to probe the neutrino predictions of some of the existing GRB models. On that account, we present here a revised, self-consistent model of joint UHE proton and neutrino production at GRBs that includes a state-of-the-art, improved numerical calculation of the neutrino flux (NeuCosmA); that uses a generalised UHECR emission model where some of the protons in the sources are able to "leak out" of their magnetic confinement before having interacted; and that takes into account the energy losses of the protons during their propagation to Earth. We use our predictions to take a close look at the cosmic ray-neutrino connection and find that the current UHECR observations by giant air shower detectors, together with the upper bounds on the flux of neutrinos from GRBs, are already sufficient to put tension on several possibilities of particle emission and propagation, and to point us towards some requirements that should be fulfilled by GRBs if they are to be the sources of the UHECRs. We further refine our analysis by studying a dynamical burst model, where we find that the different particle species originate at distinct stages of the expanding GRB, each under particular conditions. Finally, we consider a possibility of new physics: the effect of neutrino decay in the flux of UHE neutrinos from GRBs. On the whole, our results demonstrate that self-consistent models of particle production are now integral to the advancement of the field, given that the full picture of the UHE Universe will only emerge as a result of looking at the multi-messenger sky, i.e., at gamma-rays, cosmic rays, and neutrinos simultaneously.