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The PANDA experiment will be one of the flagship experiments at the future Facility for Antiproton and Ion Research (FAIR) in Darmstadt, Germany. It is a versatile detector dedicated to topics in hadron physics such as charmonium spectroscopy and nucleon structure. A DIRC counter will deliver hadronic particle identification in the barrel part of the PANDA target spectrometer and will cleanly separate kaons with momenta up to 3.5 GeV/c from a large pion background. An alternative DIRC design option, using wide Cherenkov radiator plates instead of narrow bars, would significantly reduce the cost of the system. Compact fused silica photon prisms have many advantages over the traditional stand-off boxes filled with liquid. This work describes the study of these design options, which are important advancements of the DIRC technology in terms of cost and performance. Several new reconstruction methods were developed and will be presented. Prototypes of the DIRC components have been built and tested in particle beam, and the new concepts and approaches were applied. An evaluation of the performance of the designs, feasibility studies with simulations, and a comparison of simulation and prototype tests will be presented.
Im Rahmen des FAIR Projektes wurde ein neuartiger Prototyp eines nicht strahlzerstörenden Bunch Struktur Monitors (BSM) am GSI UNILAC entwickelt. Ziel ist es, ein zuverlässiges Diagnosegerät zu entwickeln, welches die longitudinale Struktur der Ionenbunche innerhalb des LINACs untersuchen kann. Notwendig ist hierbei eine effektive Zeitauflösung deutlich unter 100 ps, bei möglichst wenigen Makropuls Mittelungen. Nach der erfolgreichen Inbetriebnahme soll der BSM Prototyp dazu dienen, die Umsetzbarkeit eines weiteren nichtinvasiven Geräts für den geplanten Proton-LINAC bei FAIR mit einer notwendigen Zeitauflösung von 10 ps zu beurteilen.
Die numerische Simulation von Materialien, welche dem Hochstrom-Ionenstrahl ausgesetzt sind, zeigten einen sehr hohen thermischen Stress. Daher wurde der Ansatz eines nicht strahlzerstörenden Diagnosegerätes verfolgt. Das Design beruht auf der Erzeugung von Sekundärelektronen durch Strahl-Restgas Kollisionen im Strahlrohr. Durch das Anlegen eines homogenen Hochspannungspotentials von bis zu -31 kV, wird ein Elektronenstrahl erzeugt, welcher die zeitliche Struktur des Ionenbunches trägt. Die zeitliche Information des Elektronenstrahles wird beim Durchfliegen eines HF-Ablenkers, welcher resonant an die 36 MHz des Beschleunigers gekoppelt ist, in eine räumliche Intensitätsverteilung umgewandelt. Anschließend wird die Elektronenverteilung auf einem bildgebenden MCP-Phosphor-Detektor durch eine CCD-Kamera detektiert und in die Bunch Struktur überführt.
Intensive Untersuchungen der BSM Eigenschaften ergaben eine höchste Auflösung von 37 ±6.3 ps bei gleichzeitig akzeptabler Intensität auf dem MCP-Detektor. Unter anderem wurden auch stabile Einzelschussmessungen durchgeführt, welche für die Profilmessung nur einen einzelnen Makropuls benötigten, statt über typischerweise 8-32 Pulse zu mitteln.
Durch die systematische Manipulation der Bunchlänge durch einen Rebuncher sind nicht gaußförmige Profile von 280 ps bis 650 ps detektiert worden, welche als Studie für eine Emittanzbestimmung genutzt worden sind. In Abhängigkeit des Analyseverfahrens sind Werte von εGauss = 1.42 ±0.14 keV/u ns bis εSD = 3.03 ±0.33 keV/u ns für die Emittanz bestimmt worden.
Des Weiteren ist ein Finite-Elemente Modell erstellt worden, um die Zeitstruktur der Sekundärelektronen innerhalb des elektronenoptischen Systems zu bestimmen. Für das Setup mit der höchsten Auflösung von 37 ps ergab sich eine zusätzliche Zeitverbreiterung von 5.6 ps, welche nur geringfügig die experimentell bestimmte Auflösung verschlechtert.
Der nicht strahlzerstörende BSM liefert eine ausreichend hohe zeitliche Auflösung für detailreiche Untersuchung der longitudinalen Bunchstruktur, ohne negative Einflüsse auf den Ionenstrahl auszuüben. Fortgeschrittene Messungen, wie longitudinale Emittanzbestimmung und Makropulsanalysen, sind möglich und werden dazu beitragen, die LINAC Strukturen besser zu verstehen und weiter zu optimieren.
Obwohl bei der Umsetzung des Arbeitsprinzips für den geplanten Proton-LINAC die veränderten Strahlparameter berücksichtigt werden müssen, zeigen die Ergebnisse, wie die Zeitstrukturuntersuchung und die erreichte Phasenauflösung von 0.5° bei 36 MHz, dass zeitliche Auflösungen bei Aufrechterhaltung der Phasenauflösung von bis zu 10 ps für einen neuen BSM Prototypen möglich sind.
Xenorhabdus and Photorhabdus bacteria are gaining more and more attention as a subject of research because of their unique yet similar life cycle with nematodes and insects. This work focused on the secondary metabolites that are produced by Xenorhabdus and Photorhabdus. With the help of modern HPLC-MS methodologies and increasingly available bacterial genome sequences, the structures of unknown secondary metabolites could be elucidated and thus their biosynthesis pathways could be proposed, too.
The first paper reported 17 depsipeptides termed xentrivalpeptides produced by the bacterium Xenorhabdus sp. 85816. Xentrivalpeptide A could be isolated from the bacterial culture as the main component. The structure of xentrivalpeptide A was elucidated by NMR and the Marfey´s method. The remaining xentrivalpeptides were exclusively identified by feeding experiments and MS fragmentation patterns.
The second paper described the discovery and isolation of xenoamicin A from Xenorhabdus mauleonii DSM17908. Additionally, other xenoamicin derivatives from Xenorhabdus doucetiae DSM17909 were analyzed by means of feeding experiments and MS fragmentation patterns. The xenoamicin biosynthesis gene cluster was identified in Xenorhabdus doucetiae DSM17909.
The manuscript for publication focused on the biosynthesis of anthraquinones in Photorhabdus luminescens. The Type II polyketide synthase for the biosynthesis of anthraquinone derivatives was discovered in P. luminescens in a previous publication by the Bode group,1 in which a partial reaction mechanism for the biosynthesis has been proposed. The manuscript reported in this thesis however elucidated the biosynthetic mechanisms in a greater detail as compared to the previous publication. Particularly, the biosynthetic mechanism was deciphered through heterologous expression of anthraquinone biosynthesis (ant) genes in E. coli. Additionally, deactivation of the genes antG encoding a putative CoA ligase and antI encoding a putative hydrolase, was performed in P. luminescens. Selected ant genes were over-expressed in E. coli as well as the corresponding proteins purified for in vitro assays. Model compounds were chemically synthesized as possible substrates of AntI and were used for in vitro assays. Here, it was revealed that the CoA ligase AntG played an essential role in the activation of the ACP AntF. Furthermore, a chain shortening mechanism by the hydrolase AntI was identified and was further confirmed by in vitro assays using model compounds. Additionally, this chain shortening mechanism was supported by homology based structural modeling of AntI.
Metal-organic frameworks (MOFs) have emerged as a promising class of crystalline porous inorganic-organic hybrid materials showing a wide range of applications. In order to realize the integration of MOFs into specific devices, this thesis mainly focuses on the controlled growth and the properties of highly oriented surface-mounted metal-organic frameworks (SURMOFs).
The stepwise layer-by-layer (LbL) growth method exhibits vast advantages for the controllable growth of SURMOFs regarding the crystallite orientation, film thickness and homogeneity. However, up to date, only a few MOFs have been demonstrated to be suited for this protocol. So the first project of this thesis was designed to extend the applicability of the LbL growth. To this end, a semi-rigid linker based [Cu2(sdb)2(bipy)] (sdb = 4,4’-sulfonylbiphenyl dicarboxylate; bipy = 4,4’-bipyridine) MOF was chosen. Employing the LbL growth, [Cu2(sdb)2(bipy)] SURMOFs were successfully grown onto both pyridyl- and carboxyl-terminated surfaces at the temperature range of 15-65 °C. Interestingly, the orientation of the SURMOFs largely depends on temperature on both surfaces. At low temperatures (below 40 °C), SURMOFs with exclusive [010] orientation are obtained. In contrast, at high temperatures (40-65 °C), [001] oriented SURMOF growth is favored. A novel growth mode was demonstrated, which is, instead of surface chemistry, the temperature-induced ripening processes and the tendency to minimize surface energies can dominate the SURMOF growth.
Inspired by the advantages of LbL deposition of isoreticular SURMOFs, the second project was conceived to grow multivariate SURMOFs (MTV-SURMOFs) using mixed dicarboxylate linkers. We advance a hypothesis that linker acidity (expressed by the pKa values) may have an influence on the oriented growth of MTV-SURMOFs. To test the hypothesis, seven isoreticular [Cu2L2(dabco)] (L = single kind of dicarboxylate linker; dabco = 1,4-diazabicyclo[2.2.2]octane) SURMOFs were grown onto pyridyl-terminated surfaces at 60 °C. The quality of [001] orientation is greatly affected by the acidity of the linkers. With this observation, we deposited a series of [Cu2Lm2(dabco)] (Lm = mixed dicarboxylate linkers) SURMOFs under the same conditions. [Cu2Lm2(dabco)] SURMOFs with exclusive [001] orientation are obtained when the growth solution contains two linkers of relatively high pKa value or more than two kinds of linkers (independent of the pKa values), while the mixtures of ligands with relatively low pKa values or a high content of low pKa valued linkers can result in mis-oriented growth of SURMOFs with unexpected [100] orientation.
Moreover, the LbL growth shows enormous potential in the rational construction of functional SURMOFs. Therefore, the third project of this thesis was devised to deposit SURMOFs containing redox-active species. For this, the 4,4’-biphenyldicarboxylic acid (H2(bpdc)) linker was functionalized with ferrocene (Fc) and dimethyl ferrocene (Me2Fc) moieties. [Cu2(bpdc-amide-Fc)2(dabco)] SURMOF (Fc-SURMOF) is perfectly grown along the [100] direction, while mis-oriented growth of [Cu2(bpdc-amide-Me2Fc)2(dabco)] SURMOF (Me2Fc-SURMOF) was observed. Surprisingly, Fc-SURMOF shows excellent electrochemical properties due to the reversible oxidation and reduction of the ferrocene moieties in the oriented pores, while the Me2Fc-SURMOF was found to be a closely packed insulating layer since no extensive charge transfer is observed. A diffusion controlled mechanism of redox reaction is proposed, where the diffusion of the counter anions in the pores limits the current.
Besides the LbL growth protocol, the spin-coating technique is also promising for the oriented growth of SURMOFs. Driven by the specific applications, the fourth project of this thesis was planned to grow functional SURMOFs containing catalytically active units. The Keggin-type polyoxometalates (POMs) with high catalytic activities were chosen to functionalize the HKUST-1 SURMOFs. Combining the technique with methanol vapor induced growth, a series of POM functionalized HKUST-1 SURMOFs (denoted as POM@HKUST-1 SURMOFs) were controllably deposited onto pyridyl-terminated surfaces. The SURMOFs exhibit great potential as electrocatalysts in electrochemical devices due to the excellent redox properties of POMs. In addition, the PTA@HKUST-1 (PTA = phosphotungstic acid) SURMOF can be employed as an ideal platform for the selective loading of methylene blue (MB) dye with high efficiency. Owing to the strong binding between the dye molecules and the framework, the MB dye cannot be desorbed by ion exchange and MB loaded PTA@HKUST-1 SURMOF shows reliable redox properties under inert conditions, further confirming the application potential in electrochemical devices.
RNA modifications are widespread in the RNA world. Nevertheless, their functions remain enigmatic. Recent analysis in tRNAs, mRNAs and rRNAs have revealed that apart from enriching their topological potential, these chemical modifications provide an added significant regulatory level to gene expression...
Das Hauptziel dieser Dissertation lag in der Verbesserung einzelner Schritte im Prozess der automatischen Proteinstrukturbestimmung mittels Kernmagnetischer Resonanz (NMR). Dieser Prozess besteht aus einer Reihe von sequenziellen Schritten, welche zum Teil bereits erfolgreich automatisiert wurden. CYANA ist ein Programmpaket, welches routinemäßig zur automatischen Zuordnung der chemischen Verschiebungen, der Nuclear Overhauser Enhancement (NOE) Signalen und der Strukturrechnung von Proteinen verwendet wird. Einer der Schritte, der noch nicht erfolgreich automatisiert wurde, stellt die Signalidentifizierung von NMR Spektren dar. Dieser Schritt ist besonders wichtig, da Listen von NMR-Signalen Grundlage aller Folgeschritte sind. Fehler in den Signallisten pflanzen sich in allen Folgeschritten der Datenauswertung fort und können am Ende in falschen Strukturen resultieren. Daher war ein Ziel dieser Arbeit, einen robusten und verlässlichen Algorithmus zur Signalidentifizierung von NMR Spektren in CYANA zu implementieren. Dieser Algorithmus sollte mit dem in FLYA implementierten Ansatz zur automatischen Resonanzzuordnung, der automatischen NOE-Zuordnung und der Strukturrechnung mit CYANA kombiniert werden. Der in CYANA implementierte CYPICK Algorithmus ahmt den von Hand durchgeführten Ansatz nach. Bei der manuellen Methode schaut sich der Wissenschaftler zweidimensionale Konturliniendarstellungen der NMR Spektren an und entscheidet anhand verschiedener Geomtrie- und Ähnlichkeitskriterien, ob es sich um ein Signal des Proteins oder um einen Artefakt handelt. Proteinsignale sind ähnlich zu konzentrischen Ellipsen und erfüllen bestimmte geometrische Kriterien, wie zum Beispiel ungefähr kreisförmiges Aussehen nach entsprechender Skalierung der spektralen Achsen und gänzlich konvexe Formen, die Artefakte nicht aufzeigen. CYPICK bewertet die Konturlinien lokaler Extrema nach diesen Bedingungen und entscheidet anhand dieser, ob es sich um ein echtes Signal handelt oder nicht. Das zweite Ziel dieser Arbeit war es ein Maß zur Quantifizierung der Information von strukturellen NMR Distanzeinschränkungen zu entwickeln. Der sogenannte Informationsgehalt (I) ist vergleichbar mit der Auflösung in der Röntgenkristallographie. Ein weiteres Projekt dieser Dissertation beschäftigte sich mit der strukturbasierten Medikamentenentwicklung (SBDD). SBDD wird meist von der Röntgenkristallographie durchgeführt. NMR hat jedoch einige Vorteile gegenüber der Röntgenkristallographie, welche interessant für SBDD sind. Daher wurden Strategien entwickelt, die NMR für SBDD zugänglicher machen sollen.
Water is scarce in semi-arid and arid regions. Using alternative water sources (i.e. non-conventional water sources), such as municipal reuse water and harvested rain, contributes to using existing water resources more efficiently and productively. The aim of this study is to evaluate the two alternative water sources reuse water and harvested rain for the irrigation of small-holder agriculture from a system perspective. This helps decision and policy makers to have proper information about which system and technology to adopt under local conditions. For this, the evaluation included ecologic, societal, economic, institutional and political as well as technical aspects. For the evaluation, the study area in central-northern Namibia was chosen in the frame of the research and development project CuveWaters. The main methods used include a mathematical material flow analysis, the computation and modelling of crop requirements, a multi-criteria decision analysis using the Analytical Hierarchy Process (AHP) method and a financial cost-benefit analysis. From a systemic perspective, the proposed novel systems were compared to the exciting conventional infrastructure. The results showed that both water reuse and rainwater harvesting systems for the irrigation of small-holder horticulture offer numerous technological, ecologic, economic, societal, institutional and political benefits. Rainwater harvesting based gardens have a positive benefit-cost ratio under favorable conditions. Government programs could fund the infrastructure investment costs, while the micro-entrepreneur can assume a micro-credit to finance operation and maintenance costs. Installing sanitation in informal settlements and reusing municipal water for irrigation reduces the overall water demand of households and agriculture by 39%, compared to improving sanitation facilities in informal settlements without reusing the water for agriculture. Given that water is the limiting factor for crop fertigation, the generated nutrient-rich reuse water is sufficient to annually irrigate about 10 m2 to 13 m2 per sanitation user. Compared to crop nutrient requirements, there are too many nutrients in the reuse water. Thus when using nutrient-rich reuse water, no use of fertilizers and a careful salt management is necessary. When comparing this novel system with improved sanitation, advanced wastewater treatment and nutrient-rich water reuse to the conventional and to two adapted systems, results showed that the novel CuveWaters system is the best option for the given context in a semi-arid developing country. Therefore, the results of this study suggest a further roll-out of the novel CuveWaters system. The methodology developed and the results of this study demonstrated that taking sanitation users into consideration plays a major role for the planning of an integrated water reuse infrastructure because they are the determinant factor for the amount of available nutrient-rich reuse water. In addition, it could be shown that water reuse and rainwater harvesting systems for the irrigation of small-scale gardens provide a wide range of benefits and can be key to using scarce water resources more efficiently and to contributing to the Sustainable Development Goals.
Light scalar mesons can be understood as dynamically generated resonances. They arise as 'companion poles' in the propagators of quark-antiquark seed states when accounting for hadronic loop contributions to the self-energies of the latter. Such a mechanism may explain the overpopulation in the scalar sector - there exist more resonances with total spin J=0 than can be described within a quark model.
Along this line, we study an effective Lagrangian approach where the isovector state a_{0}(1450) couples via both non-derivative and derivative interactions to pseudoscalar mesons. It is demonstrated that the propagator has two poles: a companion pole corresponding to a_{0}(980) and a pole of the seed state a_{0}(1450). The positions of these poles are in quantitative agreement with experimental data. Besides that, we investigate similar models for the isodoublet state K_{0}^{*}(1430) by performing a fit to pion-kaon phase shift data in the I=1/2, J=0 channel. We show that, in order to fit the data accurately, a companion pole for the K_{0}^{*}(800), that is, the light kappa resonance, is required. A large-N_{c} study confirms that both resonances below 1 GeV are predominantly four-quark states, while the heavy states are quarkonia.
In dieser Arbeit wurden die Strukturen von drei Membranproteinen mittels Einzelpartikel-Kryo‑Elektronenmikroskopie (Kryo‑EM) gelöst. Bei den Membranproteinen handelt es sich um den humanen TRP-Kanal Polycystin‑2, den sekundär-aktiven Transporter BetP aus Corynebacterium glutamicum und den Rotor-Ring der N‑Typ ATPase aus Burkholderia pseudomallei.
Kanäle sind Membranproteine, die Ionen durch eine Pore über die Membran diffundieren lassen. Durch einen präzisen, kanalabhängigen Regulationsmechanismus wird die Pore nur bei Bedarf geöffnet. TRP (transient receptor potential) Kanäle sind anhand von DNA-Sequenzvergleichen identifiziert worden und kommen ausschließlich in Eukaryonten vor. In dieser Arbeit lag der Fokus auf der Strukturbestimmung des humanen TRP Kanals Polycystin‑2 (PC‑2). PC‑2 wurde in einer Studie entdeckt, in der Patienten mit der autosomal dominanten Erbkrankheit „polyzystische Nierenerkrankung“ untersucht wurden. Patienten mit dieser Krankheit tragen eine Mutation in einem der beiden Gene PKD1 oder PKD2, welche für die Proteine Polycystin‑1 und ‑2 kodieren. In dieser Arbeit wurden verschiedene Deletionsmutanten von PC‑2 hergestellt und in das Genom menschlicher HEK293 GnTI‑ Zellen inseriert. Die Zellen, die PC‑2 bzw. die Deletionskonstrukte am stärksten synthetisierten, wurden isoliert und für die rekombinante Proteinherstellung verwendet. Die Expression von PC‑2 führte zu der Entstehung von kristalloidem endoplasmatischem Retikulum. Mutationsstudien in dieser Arbeit zeigen, dass diese morphologische Veränderung durch die Akkumulation von Membranproteinen, die mit sich selbst interagieren, begünstigt wird. Weiter ist es in dieser Arbeit gelungen, PC‑2 zu reinigen und die Struktur des Proteins mit Hilfe von Einzelpartikel Kryo-EM mit einer Auflösung von 4.6 Å zu bestimmen. Die Membrandomäne von PC‑2 ist sehr ähnlich zu den bekannten TRP Kanal Strukturen. Ein Vergleich der PC‑2 Struktur mit dem offenen und geschlossenen TRPV1 Kanal legt nahe, dass PC‑2 in seiner offenen Konformation gelöst wurde.
Der sekundär aktive Transporter BetP von C. glutamicum gehört zu der Familie der BCC- (betaine-carnitine-choline) Transporter und wird durch osmotischen Schock aktiviert. Nach seiner Aktivierung importiert BetP zwei Natriumionen und ein Glycinbetain Molekül. Durch die Akkumulierung von Glycinbetain in der Zelle steigt das osmotische Potential des Zytoplasmas, was den Wasserausstrom aus der Zelle stoppt. Viele Strukturen, die BetP in unterschiedlichen Stadien des Transportprozesses zeigen, konnten bereits mittels Röntgenkristallographie gelöst werden. Allerdings ist die N‑terminale Domäne für die Kristallisation entfernt worden und die C‑terminale Domäne, die komplett aufgelöst ist, ist an einem wichtigen Kristallkontakt beteiligt. Um strukturelle Informationen über die N‑ und C‑terminale Domäne ohne Kristallisationsartefakte zu erhalten, wurde in dieser Arbeit die Struktur von BetP mittels Einzelpartikel Kryo‑EM bestimmt. Die Struktur mit einer Auflösung von 6.8 Å zeigt BetP in einem zum Zytoplasma geöffneten Zustand. Der größte Unterschied zu allen Kristallstrukturen ist die Position der C‑terminalen α‑Helix, die um ~30° rotiert ist und dadurch deutlich enger am Protein zu liegen kommt. Da BetP in Abwesenheit von aktivierenden Stoffen analysiert wurde, wird vermutet, dass es sich bei der gelösten Struktur um den inaktiven Zustand von BetP handelt.
Rotierende ATPasen sind membrangebunden Enzymkomplexe, die bei der zellulären Energieumwandlung eine entscheidende Rolle einnehmen. Sie bestehen aus einem löslichen und einem membrangebundenen Teil. Während in dem löslichen Teil der zelluläre Energieträger Adenosintriphosphat (ATP) entweder synthetisiert oder hydrolysiert wird, baut der membrangebundene Teil entweder einen Ionengradienten auf oder nutzt die Energie eines existierenden Gradienten für die ATP Synthese. Ein wesentlicher Bestandteil des membrangebundenen Teils einer rotierenden ATPase ist der Rotor-Ring. Dieser transportiert Ionen über die Membran und rotiert dabei um seine eigene Achse. In dieser Arbeit wurde eine Studie fortgesetzt, die den Rotor-Ring der N‑Typ ATPase von B. pseudomallei mittels Kryo‑EM untersuchte und zeigte, dass der Rotor-Ring aus 17 identischen Untereinheiten aufgebaut ist. Damit hat die N‑Typ ATPase das größte Ionen-zu-ATP-Verhältnis aller bisher charakterisierten ATPasen. In dieser Arbeit wurde die c17 Stöchiometrie des N‑Typ ATPase Rotor-Rings bestätigt und die Struktur mittels Kryo‑EM bestimmt. Im besonderen Fokus lag dabei der Einfluss von Detergenzien auf die Strukturbestimmung. Es konnte gezeigt werden, dass die beiden Parameter Dichte und Mizellengröße der verwendeten Detergenzien ausschlaggebend für den Erfolg der Strukturbestimmung dieses sehr kleinen Membranproteins sind.
This PhD thesis has been carried out within an interdisciplinary cooperational project between the Deutsches Bergbau-Museum Bochum and the Goethe-Universität Frankfurt, which is dedicated to ancient Pb-Ag mining and metal production in the hinterland of the municipium Ulpiana in central Kosovo. Geochemical analysis (OM, XRD, EMP, MC-ICP-MS) of ores, metallurgical (by-) products and metal artefacts allowed to reconstruct the local chaîne opératoire and to decipher significant chronological differences between presumably Roman/late antique and medieval/early modern metallurgical processing. Pb isotope provenance studies documented the relevance of local metal production within the Roman Empire and confirmed the actual existence of a Metalla Dardanica district, which until now solely has been suspected on basis of epigraphy.
The predominant abundance of the by-products matte (Cu, Pb, Fe and Zn sulphides) and speiss (ferrous speiss: Fe-As compounds; base metal speiss: ~(Cu,Ni,Fe,Ag )x(Sb,Sn,As )y ) at smelting sites with a preliminary Roman/late antique dating points to treatment of complex polymetallic ore. Pb isotope analysis demonstrated that the mining district of Shashkoc-Janjevo (partially) supplied six of the ten investigated metallurgical sites. In this mineralisation, parageneses with elevated Cu, As and Sb abundances comprise significant proportions of particularly tennantite-tetrahedrite minerals, chalcopyrite, arsenopyrite and were generated during the early and main stages of ore formation. Later precipitated ore in contrast is marked by a significantly less versatile mineralogy and consists almost exclusively of galena, sphalerite and pyrite/marcasite. Besides increased Cu, As and Sb contents, ore from the main formation stage also exhibits generally higher Ag abundances, which are mainly hosted by fahlore and locally abundant secondary Cu sulphides (chalcocite, digenite and covellite) and oxidised phases (e.g. malachite, azurite). The higher precious metal grades of this ore type, whose geochemical signature (i.e. higher proportions of Cu, As and Sb) is mirrored by the abundance of the metallurgical by-products matte and speiss (almost exclusively found at potentially Roman/late antique smelting sites; see above), presumably were a pivotal factor leading to its preferential exploitation in earlier times. Matte and base metal-rich speiss contain notable amounts of Ag, which are mainly present in Cu-(Fe) sulphides and particularly antimonides ((Cu,Ni)2Sb, Ag3Sb), respectively. While the speiss compounds due to their close association with Pb bullion presumably were cupelled automatically, the metallurgical treatment of matte could not have been proven unambiguously, but overall certainly is highly likely.
The beneficiated ore (i.e. crushed and sorted, potentially also treated by more lavish techniques such as grinding, sieving or wet-mechanical methods) possibly was partially roasted and subsequently together with fluxes and charcoal submitted to the furnaces. The working temperatures approximately ranged between 1100 and 1400 °C. Slags from all presumably Roman/late antique dated and few of their potentially medieval/early modern analogues were produced from smelting of (partially roasted) ore with charcoal and added siliceous material, thus resulting in fayalite-dominant phase assemblages or rarely observed glassy parageneses. Even though several subtypes of fayalite slags have been established on basis of the abundance of Fe-rich oxide phases (i.e. spinel ss and wüstite), late clinopyroxene and the general solidification sequence of the slags, the process conditions (i.e. temperature, fO2, added fluxing agents) must have been widely similar; chemical variations could be explained by varying degrees of interaction of the slag melt with charcoal ash and furnace material. The other investigated metallurgical remains indicate employment of a calcareous flux, which led to formation of Ca-rich olivine-, olivine+clinopyroxene-, clinopyroxene- or melilite-type slags. These types as well as glassy slags were generated at more oxidising conditions outside the fayalite stability field (FMQ buffer equilibrium, cf. Lindsley, 1976) than their olivine-dominant analogues. Conclusions on the furnace construction could be drawn on basis of the typology of the slags, which mostly were tapped into a basin located outside the furnace, but partially (at two presumably medieval/early modern sites) also accumulated in a reservoir within the smelter.
Lead artefacts excavated in Ulpiana could be isotopically related to ores from mineralisations in its vicinity and demonstrate that the resources were at least utilised for local metal production. However, also ship wreck cargo from Israel - including several lead ingots with the inscription 'MET DARD' (Raban, 1999) - and late antique lead-glazed pottery from Serbia and Romania (Walton & Tite, 2010) could be related to a possible Kosovarian/Serbian provenance of the raw material and thus indicate flourishing trade of metal from the Metalla Dardanica district within the Roman Empire.
References:
Lindsley, D. H. (1976). Experimental studies of oxide minerals. In D. Rumble, III (Hrsg.), Oxide minerals (61-88). Reviews in Mineralogy, Volume 3. Washington, DC: Mineralogical Society of America.
Raban, A. (1999). The lead ingots from the wreck site (area K8). Journal of Roman Archaeology, Supplementary Series, 35, 179-188.
Walton, M. S., & Tite, M. S. (2010). Production technology of Roman lead-glazed pottery and its continuance into late antiquity. Archaeometry, 52(5), 733-759.
Embryonale Stammzellen (ESCs) sind ein wichtiges Werkzeug zur Untersuchung der frühen embryonalen Entwicklung. ESCs können mit Hilfe neuer Technologien zur Modifikation von Genen (z.B. mit dem CRISPR/Cas9 System) genetisch manipuliert werden. Daraus resultierende „knockout“ ES Zelllinien können helfen, die physiologische Rolle von Proteinen während der Differenzierung zu verstehen.
Transkriptionsfaktoren, die schnell und spezifisch Signalwege regulieren, spielen während der Embryonalentwicklung und während der Differenzierung von ESCs in vielen verschiedenen Zelltypen eine essentielle Rolle. Der Transkriptionsregulator „Far Upstream Binding Protein 1“ (FUBP1) ist ein Protein, welches eine ganz bestimmte einzelsträngige DNA Sequenz, das „Far Upstream Sequenz Element“, erkennt, bindet, und dadurch Gene wie z.B c-myc oder p21 reguliert. Mit der Entwicklung zweier Fubp1 Genfallen Mausstämme (Fubp1 GT) sollte die Frage nach der physiologischen Funktion von FUBP1 beantwortet werden. Die homozygoten FUBP1-defizienten GT Embryonen sterben im Mutterleib ungefähr am Tag E15.5 der Embryonalentwicklung. Sie sind kleiner als Wildtypembryonen und zeigen ein anämisches Aussehen. Daher wurden diese Mausmodelle hinsichtlich der Hämatopoese untersucht, die zu diesem Zeitpunkt vor allem in der Leber stattfindet. Es konnte eine signifikante Reduktion der hämatopoetischen Stammzellen (HSCs) festgestellt werden und zusätzlich war die langfristige Repopulation der FUBP1-/--Stammzellen im Knochenmark in Transplantationsexperimenten reduziert.
In der vorliegenden Arbeit wurde die Rolle von FUBP1 in einem weiteren Stammzellsystem analysiert und gleichzeitig seine Bedeutung in anderen Zelltypen der frühen Embryonalentwicklung untersucht.
Die Quantifizierung der FUBP1 Expression in den ESCs und während der Differenzierung zu sogenannten `embryoid bodies` (EBs) zeigten eine starke Expression auf mRNA- und auf Proteinebene. Nach der erfolgreichen Optimierung der Differenzierung von murinen ESCs wurden Fubp1 „knockout“ (KO) ESC Klone mit Hilfe der CRISPR/Cas9 Technologie etabliert. Die molekularbiologische Analyse der ESCs zeigte eine signifikante Erhöhung der Oct4 mRNA-Expression, während Nanog und die Differenzierungsmarker Brachyury, Nestin und Sox17 unverändert und in vergleichbarer Menge zu den Kontrollen vorhanden waren. Während der Differenzierung der Fubp1 KO Klone zu EBs zeigte sich eine signifikante Reduktion mesodermaler Marker wie Flk-1, SnaiI, Snai2, Bmp4 und FgfR2. Mit Hilfe durchflusszytometrischer Analysen bestätigte sich die verzögerte Bildung mesodermaler Zellen (Brachyury- und Flk-1-exprimierender Zellen) in den Fubp1 KO Klonen der EBs an den Tagen 3, 4 und 5 nach Beginn der Differenzierung.
Die Anwendung einer Ko-Kultivierung auf OP9 Zellen zur Differenzierung der ESCs in hämatopoetische Linien sollte zeigen, ob der Fubp1 KO ESCs ein Defekt in der frühen Entwicklung hämatopoetischer Stammzellen zu beobachten ist. Erneut konnte am Tag 5 der ESC-Differenzierung in der OP9 Ko-Kultur eine signifikante Reduktion der mesodermalen (Flk-1+) Zellen festgestellt werden. Die weitere Differenzierung zu hämatopoetischen CD45+ Zellen zeigte jedoch keinen Unterschied im prozentualen Anteil CD45+ Zellen am Tag 12 der Differenzierung. Auch die gezielte Differenzierung zu erythroiden Zellen durch Zugabe des Zytokins EPO zum Medium zeigte keinen signifikanten Unterschied im Differenzierungsgrad der erythroiden Zellen zwischen Kontroll- und Fubp1 KO Klonen.
In weiteren Experimenten habe ich in dieser Arbeit die Expression von FUBP1 in WT Embryos an den Tagen E9.5 und E13.5 der Embryonalentwicklung untersucht. Hierbei zeigte sich in beiden Entwicklungsstadien eine immunhistochemische Anfärbung von FUBP1 in den meisten Zellen des Embryos. Die Annahme, dass die Abwesenheit von FUBP1 in der Embryonalentwicklung zu verstärkten apoptotischen Vorgängen führen könnte und gleichzeitig die massive Expansion von Zellen gestört sein könnte wurde mit Hilfe immunhistochemischer Färbung von „cleaved Caspase 3“ (Apoptosemarker) und „Ki-67“ (Proliferationsmarker) in den homozygoten Fubp1 GT Embryos an den Tagen E9.5 und E13.5 nicht bestätigt.
Die Ergebnisse dieser Arbeit lassen darauf schließen, dass die Regulation von Apoptose und Proliferation durch FUBP1 während der Embryonalentwicklung nicht die Hauptrolle von FUBP1 darstellt. Es zeigte sich jedoch, dass FUBP1 als Transkriptionsregulator wichtig für die mesodermale Differenzierung von ESCs ist. Zu beobachten war, dass es in den FUBP1-defizienten ESCs zu einer Verzögerung der mesodermalen Differenzierung kommt. Es konnte bereits gezeigt werden, dass FUBP1 essenziell für die Selbsterneuerung von HSCs ist. Dies macht deutlich, dass FUBP1 neben der Proliferation und Apoptose ein breiteres Spektrum an Signalwegen reguliert, die für Stammzellen und deren Differenzierung von Bedeutung sind.
Photoinduzierte Energietransferprozesse und -reaktionen spielen in vielen Gebieten von Chemie, Physik und Biologie eine wichtige Rolle. Zu den prominentesten Beispielen zählen der Lichtsammelprozess in der Photosynthese und der Anregungsenergietransfer in funktionellen Materialien. Der Fokus dieser Arbeit liegt auf letzterem Bereich, genauer auf organischer Elektronik und flexiblen Donor-Akzeptor-Bausteinen und Schaltern. Im Besonderen werden hier zwei verschiedene Typen von funktionellen organischen Systemen betrachtet: zum einen oligomere Fragmente organischer halbleitender Polymere wie Oligo-p-Phenylen-Vinylen (OPV) und Oligo-Thiophen (OT), welche als Bausteine für neuartige organische Solarzellen dienen, und zum anderen kleine funktionelle Donor-Akzeptor-Einheiten wie Dithienylethen-Bordipyrromethen (DTE-BODIPY). Letzteres wurde in Kooperation mit den experimentellen Gruppen von K. Rück-Braun (TU Berlin) und J. Wachtveitl (Goethe Universität) untersucht. Um die relevanten Energietransfermechanismen genauer zu verstehen, wurden an diesen Systemen elektronische Strukturrechnungen und quantendynamische Untersuchungen durchgeführt. Hierzu wurden mittels ab initio-Methoden Modell-Hamiltonians parametrisiert und mit hochdimensionalen quantendynamischen oder semiklassischen Methoden kombiniert. Während die Parametrisierung für kleinere Fragmente durchgeführt wurde, lässt sich der so parametrisierte Hamiltonian ohne Weiteres auf größere Systeme erweitern. Die dynamischen Studien der betreffenden Systeme wurden mittels der Multikonfigurationellen Zeitabhängigen Hartree (MCTDH) Methode durchgeführt, welche eine vollständige quantendynamische Beschreibung des Systems zulässt. Für größere Systeme wurde die semiklassische Ehrenfest Methode in Verbindung mit dem Langevin-Ansatz zur Beschreibung von Umgebungseffekten genutzt. Hierzu wurde ein eigens für diese Methode und Systeme geschriebenes Programm eingesetzt. Im Falle der OT- und OPV-Oligomere wurde die Dynamik bei Vorliegen eines strukturellen Defekts untersucht. Ziel war es hierbei, die dynamischen Phänomene, welche durch die Photoanregung induziert werden, zu untersuchen. Des Weiteren wurde untersucht, ob das Konzept von „spektroskopischen Einheiten“, welche die Lokalisierung der Anregung durch strukturelle Defekte beschreibt, in diesen Systemen zutrifft. Hierzu wurden die Systeme in einer Frenkel-Basis definiert, welche ein auf einem Monomer lokalisiertes Elektron-Loch-Paar beschreibt. Delokalisierte elektronische Anregungen können somit als Superposition solcher Frenkel-Zustände beschrieben werden. Neben der Frenkel-Basis wurde aber auch eine verallgemeinerte Elektron-Loch-Basis verwendet, welche über zusätzliche Ladungstransferzustände eine räumliche Separation von Elektronen und Löchern erlaubt.Die Parametrisierung des OPV- und OT-Hamiltonians erfolgte mittels der Algebraischen Diagrammatischen Konstruktions (ADC(2))-Methode, welche in Kombination mit einer Übergangs-Dichte-Matrix-Analyse eine sehr akkurate Beschreibung der Frenkel- und Ladungstransferzustände basierend auf den supermolekularen Zuständen erlaubt. Um vibronische Effekte auf die Dynamik miteinzubeziehen,wurden nieder- und hochfrequente Torsions- und alternierende Bindungslängenmoden des Systems im Hamiltonian berücksichtigt. Hierzu wurden eindimensionale Schnitte der Potentialflächen entlang dieser Koordinaten berechnet und mittels einer Transformation in diabatische Potentialflächen überführt. Mit diesem Setup wurden die quantendynamischen und semiklassischen Simulationen für ein OPV/OT-Hexamer und ein 20-mer durchgeführt. Die Ergebnisse dieser Simulationen zeigen, dass der Energietransfer auf einer Subpikosekunden-Zeitskala stattfindet und eine starke Abhängigkeit vom Vorliegen eines strukturellen Defekts aufweist. Des Weiteren konnte auf einer Zeitskala von 100 Femtosekunden eine Lokalisierung des Exzitons beobachtet werden. Fluktuationseffekte werden zudem über Quantenfluktuationen im Falle von MCTDH bzw. über thermische Fluktuationen im Falle des Ehrenfest-/Langevin-Ansatzes berücksichtigt. Letzterer ist jedoch nicht in der Lage, die kohärente Charakteristik der mit den Schwingungsmoden gekoppelten Exziton- und Lokalisierungsdynamik wiederzugeben. Dagegen kann dieser Ansatz erfolgreich genutzt werden, um eine fluktuationsgetriebene „Hopping“-Dynamik des quasi- stationären Zustandes auf einer längeren Zeitskala in Abhängigkeit von der Temperatur zu beschreiben. Die Beschreibung der Photodynamik der DTE-BODIPY-Dyade zielt darauf ab, experimentell beobachtete vibrationelle Schwingungen des BODIPY-Fragments zu erklären, die ohne eine direkte Anregung dieses Fragments zustande kommen. Diese wurden nach einer selektiven Anregung des DTE-Fragments in zeitaufgelösten UV/Vis Anreg-Abtast-Experimenten beobachtet. Der Fokus der Untersuchung liegt daher auf der Beschreibung der photoinduzierten intramolekulare Energieumverteilung (IVR) auf einer Subpikosekunden-Zeitskala. Die DTE-BODIPY Dyade wurde mittels eines Hamiltonians, welcher durch TDDFT Rechnungen parametrisiert wurde, dargestellt. Basierend auf den Normalmoden des Systems, wurden lokale DTE- und BODIPY-Moden konstruiert, wobei einige dieser Moden miteinander gekoppelt sind und die Photoanregung des DTE auf das BODIPY-Fragment übertragen. Hierbei zeigte sich, dass die Zeitskala und die charakteristischen Frequenzen des Experiments mittels der hochdimensionalen MCTDH-Methode gut reproduziert wurden. Aus den Simulationen ergab sich zudem, dass der beobachtete Energietransfer stark von einem Reservoir von vibrationell angeregten lokalen DTE-Moden beeinflusst wird. Der untersuchte IVR- Prozess zeigt zudem eine ausgeprägte Abhängigkeit von lokalen Kopplungen und der Kopplung an eine Umgebung.
Nanomaterials, i.e., materials that are manufactured at a very small spatial scale, can possess unique physical and chemical properties and exhibit novel characteristics as compared to the same material without nanoscale features. The reduction of size down to the nanometer scale leads to the abundance of potential applications in different fields of technology. For instance, tailoring the physicochemical properties of nanomaterials for modification of their interaction with a biological environment has been reflected in a number of biomedical applications.
Strategies to choose the size and the composition of nanoscale systems are often hindered by a limited understanding of interactions that are difficult to study experimentally. However, this goal can be achieved by means of advanced computer simulations. This thesis explores, from a theoretical and a computational viewpoints, stability, electronic and thermo-mechanical properties of nanoscale systems and materials which are related to biomedical applications.
We examine the ability of existing classical interatomic potentials to reproduce stability and thermo-mechanical properties of metal systems, assuming that these potentials have been fitted to describe ground-state properties of the perfect bulk materials.
It is found that existing classical interatomic potentials poorly describe highly-excited vibrational states when the system is far from the potential energy minimum. On the other hand, construction of a reliable computational model is essential for further development of nanomaterials for applications. A new interatomic potential that is able to correctly reproduce both the melting temperature and the ground-state properties of different metals, such as gold, platinum, titanium, and magnesium, by means of classical molecular dynamics simulations is proposed in this work. The suggested modification of a many-body potential has a general nature and can be utilized for similar numerical exploration of thermo-mechanical properties of a broad range of molecular and solid state systems experiencing phase transitions.
The applicability of the classical interatomic potentials to the description of nanoscale systems, consisting of several tens-hundreds of atoms, is also explored in this study. This issue is important, for instance, in the case of nanostructured materials, where grains or nanocrystals have a typical size of about a few nanometers. We validate classical potentials through the comparison with density-functional theory calculations of small
atomic clusters made of titanium and nickel. By this analysis, we demonstrate that the classical potentials fitted to describe ground-state properties of a bulk material can describe the energetics of nanoscale systems with a reasonable accuracy.
In this work, we also analyze electronic properties of nanometer-size nanoparticles made of gold, platinum, silver, and gadolinium; nanoparticles composed of these materials are of current interest for radiation therapy applications. We focus on the production of low-energy electrons, having the kinetic energy from a few electronvolts to several tens of electronvolts. It is currently established that the low-energy secondary electrons of such energies play an important role in the nanoscale mechanisms of biological damage resulting from ionizing radiation. We provide a methodology for analyzing the dynamic response of nanoparticles of the experimentally relevant sizes, namely of about several nanometers, exposed to ionizing radiation. Because of a large number of constituent atoms (about 1000 −10000 atoms) and consequently high computational costs, the electronic properties of such systems can hardly be described by means of ab initio methods based on a quantum-mechanical treatment of electrons, and this analysis should rely on model approaches. By comparing the response of smaller systems (of about 1 nm size) calculated within the ab initio- and the model framework, we validate this methodology and make predictions for the electron production in larger systems.
We have revealed that a significant increase in the number of the low-energy electrons emitted from nanometer-size noble metal nanoparticles arises from collective electron excitations formed in the systems. It is demonstrated that the dominating mechanisms of electron yield enhancement are related to the formation of plasmons excited in a whole system and of atomic giant resonances formed due to excitation of valence d electrons in individual atoms of a nanoparticle. Being embedded in a biological medium, the noble metal nanoparticles thus represent an important source of low-energy electrons, able to produce a significant irrepairable damage in biological systems.
A general methodology for studying electronic properties of nanosystems is used to make quantitative predictions for electron production by non-metal nanoparticles. The analysis illustrates that due to a prominent collective response to an external electric field, carbon nanoparticles embedded in a biological medium also enhance the production of low-energy electrons. The number of low-energy electrons emitted from carbon nanoparticles is demonstrated to be several times higher as compared to the case of liquid water.
The phenomenon of magnetism has been known to humankind for at least over 2500 years and many useful applications of magnetism have been developed since then, starting from the compass to modern information storage and processing devices. While technological applications are an important part of the continuing interest in magnetic materials, their fundamental properties are still being studied, leading to new physical insights at the forefront of physics. The magnetism of magnetic materials is a pure quantum effect due to the electrons that carry an intrinsic spin of 1/2. The physics of interacting quantum spins in magnetic insulators is the main subject of this thesis.We focus here on a theoretical description of the antiferromagnetic insulator Cs2CuCl4. This material is highly interesting because it is a nearly ideal realization of the two-dimensional antiferromagnetic spin-1/2 Heisenberg model on an anisotropic triangular lattice, where the Cu(2+) ions carry a spin of 1/2 and the spins interact via exchange couplings. Due to the geometric frustration of the triangular lattice, there exists a spin-liquid phase with fractional excitations (spinons) at finite temperatures in Cs2CuCl4. This spin-liquid phase is characterized by strong short-range spin correlations without long-range order. From an experimental point of view, Cs2CuCl4 is also very interesting because the exchange couplings are relatively weak leading to a saturation field of only B_c=8.5 T. All relevant parts of the phase diagram are therefore experimentally accessible. A recurring theme in this thesis will be the use of bosonic or fermionic representations of the spin operators which each offer in different situations suitable starting points for an approximate treatment of the spin interactions. The methods which we develop in this thesis are not restricted to Cs2CuCl4 but can also be applied to other materials that can be described by the spin-1/2 Heisenberg model on a triangular lattice; one important example is the material class Cs2Cu(Cl{4-x}Br{x}) where chlorine is partially substituted by bromine which changes the strength of the exchange couplings and the degree of frustration.
Our first topic is the finite-temperature spin-liquid phase in Cs2CuCl4. We study this regime by using a Majorana fermion representation of the spin-1/2 operators motivated by theoretical and experimental evidence for fermionic excitations in this spin-liquid phase. Within a mean-field theory for the Majorana fermions, we determine the magnetic field dependence of the critical temperature for the crossover from spin-liquid to paramagnetic behavior and we calculate the specific heat and magnetic susceptibility in zero magnetic field. We find that the Majorana fermions can only propagate in one dimension along the direction of the strongest exchange coupling; this reduction of the effective dimensionality of excitations is known as dimensional reduction.
The second topic is the behavior of ultrasound propagation and attenuation in the spin-liquid phase of Cs2CuCl4, where we consider longitudinal sound waves along the direction of the strongest exchange coupling. Due to the dimensional reduction of the excitations in the spin-liquid phase, we expect that we can describe the ultrasound physics by a one-dimensional Heisenberg model coupled to the lattice degrees of freedom via the exchange-striction mechanism. For this one-dimensional problem we use the Jordan-Wigner transformation to map the spin-1/2 operators to spinless fermions. We treat the fermions within the self-consistent Hartree-Fock approximation and we calculate the change of the sound velocity and attenuation as a function of magnetic field using a perturbative expansion in the spin-phonon couplings. We compare our theoretical results with experimental data from ultrasound experiments, where we find good agreement between theory and experiment.
Our final topic is the behavior of Cs2CuCl4 in high magnetic fields larger than the saturation field B_c=8.5 T. At zero temperature, Cs2CuCl4 is then fully magnetized and the ground state is therefore a ferromagnet where the excitations have an energy gap. The elementary excitations of this ferromagnetic state are spin-flips (magnons) which behave as hard-core bosons. At finite temperatures there will be thermally excited magnons that interact via the hard-core interaction and via additional exchange interactions. We describe the thermodynamic properties of Cs2CuCl4 at finite temperatures and calculate experimentally observable quantities, e.g., magnetic susceptibility and specific heat. Our approach is based on a mapping of the spin-1/2 operators to hard-core bosons, where we treat the hard-core interaction by the self-consistent ladder approximation and the exchange interactions by the self-consistent Hartree-Fock approximation. We find that our theoretical results for the specific heat are in good agreement with the available experimental data.
Modern mobile devices offer a great variety of data that can be recorded. This broad range of information offers the possibility to tailor applications more to the needs of a user. Several context information can be collected, like e.g. information about position or movement. Besides integrated sensors, a broad range of additional sensors are available which can be connected to a mobile device. These additional sensors offer for example the possibility to measure physiological signals of a user.The human body offers a broad range of different signals. These signals have been used in several examples to conclude on the state of a user. The different signals allow to get a deeper insight into emotional or mental state of a user. Electrodermal activity gives feedback about the current arousal level of a user. Heart rate and heart rate variability can give an estimation about valence and mental load of a user. Several models exist to conclude from information like valence and arousal on different emotional states. Russell defined a two dimensional model, using valence and arousal to define affective states. Yerkes and Dodson developed a curve that expresses the relationship between arousal and performance of a user. Different examples exist, that use physiological signals to determine the user state for tailoring and adapting of applications. At the time of this work most of these examples did not address the usage of physiological signals for user state estimation in mobile applications and in mobile scenarios. Mobile scenarios lead to several challenges that need to be addressed. Influencing factors on physiological signals, like e.g. movement have to be controlled. Furthermore a user might be interrupted and influenced by environmental aspects. The combination of physiological data and context information might improve the interpretation of user state in mobile scenarios. In this work, we present a model that addresses the challenges of usage in mobile scenarios to offer an estimation of user state to mobile applications. To address a broad range of mobile applications, affective and cognitive state are provided as output. As input heart rate and electrodermal activity are used, as well as context information about movement and performance. Electrodermal activity is measured by a simple sensor that can be worn as a wristband. Heart rate is measured by a chest strap as used in sports. The input channels are transformed to affective and cognitive state based on a fuzzy rule based approach. With help of fuzzy logic, uncertainty can be expressed and the data continuously being processed. At the start, input channels are fuzzified by defined functions. After a that, a first fuzzy rule set transforms the input signals into values for valence, arousal and mental load. In a second step, these values and context information are transformed with another fuzzy rule set to values for affective and cognitive state. Affective state is based on the model of Russell, where valence and arousal are used to determine different emotional states. The output of the model are eight different affective states (alarmed, excited, happy, relaxed, tired, bored, sad and frustrated), which can have a high, medium, low or very low value as output. Cognitive state is determined based on mental load and context information about performance and movement. The output value can be very high, high, medium or low. The model was implemented as background service for Android devices. Different applications have been used for evaluation of the model. The model has been integrated in a multiplayer space shooter game, called ”Zone of Impulse”, which mainly benefits from the affective state. Cognitive state is more addressed in applications like a simple vocable trainer, which adapts difficulty based on user state. A study to evaluate different aspects of the model has been conducted. The study was designed to investigate the suitability of the model for mobile scenarios. The game ”zone of impulse” and the vocable trainer have been investigated in different configurations. Versions with integrated model have been compared to version of the applications without model, as well as versions of the model without context information. In total 41 participants took part in the study. A part of the participants had to do the tasks of the study in a mobile scenario, walking around several streets. The remaining participants had to do the tasks in a controlled environment in a sitting position. Different aspects were collected with ratings and questionnaires. Overall, participants rated that they did not feel impaired by the sensors they had to wear. The results showed, that the combination of physiological data and context information had an advantage against versions without context information in part of the ratings. A comparison between versions with and without model showed, that the subjective mental load ratings were significantly better for the version with model. Subjective ratings for aspects like fun, overstrain and support were mixed. When comparing the application versions in indoor and outdoor scenarios, no significant difference could be found, which leads to the assumption that there is no loss of interpretation quality in outdoor scenarios. The results also showed that the model seems to be robust enough to compensate the loss of an input channel, as there was no significant difference between application versions with full integrated model and versions with one channel lost. With the model developed in this work, context information and physiological data were combined to improve user state estimation. Furthermore pitfalls of user state estimation in mobile scenarios are overcome with this combination. However, the model has only been evaluated with a limited amount of applications and situations that mobile scenarios offer.
Für die Optimierung sowie Entwicklung lichtsteuerbarer Systeme für biologische Anwendungen oder neue Materialien ist ein detailliertes Verständnis der zugrunde liegenden komplexen, lichtinduzierten Prozesse eine Voraussetzung. Die Verwendung von Photoschaltern in Makromolekülen ermöglicht eine zeitliche und örtliche Kontrolle über strukturelle Änderungen sowie die entsprechend folgenden (biologischen) Funktionen durch die Verwendung von Licht als externem Auslöser.
Ein wichtiger Bestandteil dieser Arbeit befasst sich mit der Entwicklung eines auf Licht reagierenden Riboschalters, welcher die gezielte Kontrolle über Genexpression ermöglicht. Hierzu wurde eine spektroskopische Charakterisierung von verschiedenen Photoschaltern bezüglich einer Verwendung als biologischer Ligand sowie der Wechselwirkungen zwischen Azobenzolen und RNA, auch hinsichtlich ihrer Bindungsdynamiken durchgeführt. Zunächst wurde die hohe Abhängigkeit der (photo-)chemischen Eigenschaften der Azobenzole von der Wahl der Substituenten untersucht, wobei besonders die Anwendung in wässrigem Milieu betrachtet wurde. In einer detaillierten (zeitaufgelösten) Studie wurde der positionsabhängige Einfluss der Hydroxy-Substitution von Azobenzolen auf die Photoisomerisierung in wässriger Lösung untersucht. Für eine ortho-Substitution ergab sich hierbei ein alternativer Deaktivierungskanal nach Photoanregung, welcher stärker ausgeprägt ist als die Isomerisierung. Hierbei wird ein intramolekularer Protontransfer im angeregten Zustand (ESIPT) beobachtet, welcher mit einer Zeitkonstante von 0.3 ps beschrieben werden kann und in einer Keto-Spezies resultiert. Eine Keto-Enol-Tautomerie konnte für die para-Hydroxy-Substitution schon im Grundzustand beobachtet werden. Somit können beide Spezies gezielt adressiert werden. Durch Acetylierung der Hydroxygruppe verlangsamt sich die thermische Relaxation des cis-Isomer zu dem entsprechenden trans-Isomer signifikant ohne die Isomerisierung zu beeinträchtigen. Dementsprechend ermöglicht eine solche Acetylierung die Verwendung von bekannten Azobenzolderivaten als Photoschalter.
Zudem werden in dieser Arbeit zwei verschiedene Herangehensweisen in der Entwicklung eines Riboschalters beschrieben, welcher sich durch Licht regulieren lässt.
Diese sind durch kovalentes bzw. nicht-kovalentes Einbringen eines Azobenzolderivats in die RNA Struktur charakterisiert. Ein neuer Linker, welcher auf einer Desoxyribose-Struktur beruht, wird für die kovalente Anbindung des Azobenzols an den RNA Strang präsentiert, welcher eine licht-induzierte Dehybridisierung ermöglichen soll. Eine außergewöhnlich hohe Schaltamplitude mit einem cis-Gehalt von etwa 90% konnte für das Azobenzol im RNA Einzelstrang schon bei Raumtemperatur ermittelt werden. Zudem wurde der Einfluss des Photoschalters sowie der benachbarten Nukleotide in der RNA auf die Stabilität der RNA Doppelhelix untersucht. Die zweite Vorgehensweise beruht auf einer nicht-kovalenten Bindung zwischen einem Azobenzolderivat und einem RNA-Aptamer, welche lediglich für eines der Photoisomere ermöglicht wird, wodurch eine örtliche und zeitliche Kontrolle der Ligandenbindung der RNA erfolgt. Im Rahmen dieser Arbeit war es möglich zwei verschiedene photoschaltbare RNA Aptamere zu identifizieren und zu untersuchen, welche eine hohe Spezifität und Affinität aufweisen. Zudem wurde die Photoisomerisierung des Azobenzols innerhalb der RNA-Struktur sowie daraus resultierende lichtinduzierte Konformationsänderungen der RNA mittels zeitaufgelöster Anreg-/Abtastspektroskopie untersucht. Die daraus resultierende Dynamik der photoinduzierten Ligandenbindung sollte eine weitere gezielte Optimierung lichtschaltbarer biologischer Systeme erlauben.
Der zweite Teil dieser Arbeit beschäftigt sich mit der zeitaufgelösten Untersuchung eines photoschaltbaren Foldamers. Speziell wurde der strukturelle Übergang des OmPE-Foldamers 10-5 zwischen einer definierten helikalen und einer ungefalteten Konformation auf Grund der Photoisomerisierung der, in das Rückgrat integrierten, Azobenzole untersucht.
Dabei konnten die frühen (Ent-)Faltungsmechanismen des Foldamers im sub-Nanosekunden-Zeitbereich beobachtet werden, welche durch quantenmechanische Rechnungen unterstützt werden konnten. Darüberhinaus, war es möglich einen Anregungsenergietransfer vom PE-Rückgrat des Foldamers auf die Azobenzole nachzuweisen, welcher die Lebensdauer der angeregten Zustände des Systems signifikant verkürzt.
Diese Arbeit liefert wichtige Informationen zu den Reaktionspfaden, den gezielten Wechselwirkungen zwischen Photoschaltern und größeren organischen Molekülen, sowie den daraus resultierenden lichtinduzierten strukturellen Änderungen durch die Anwendung einer Vielzahl an (zeitaufgelösten) spektroskopischen Methoden. Diese Ergebnisse tragen zum weiteren Verständnis komplexer Prozesse in biologischem sowie nicht-biologischem Zusammenhang und somit zu einer weiterführenden Entwicklung neuer Systeme bei.
In the adult mammalian brain stem cells within defined neurogenic niches retain the capacity for lifelong de novo generation of neurons. The subventricular zone (SVZ) of the lateral ventricles and the subgranular layer (SGL) of the hippocampal dentate gyrus (DG) have been identified as the two major sites of adult neurogenesis. Moreover, the third ventricle in the hypothalamus is emerging as a new neurogenic niche in the adult brain. Extracellular purine and pyrimidine nucleotides are involved in the control of both embryonic and adult neuro-genesis. These nucleotides act via ionotropic P2X or metabotropic P2Y receptors and studies of the adult SVZ and the DG provide strong evidence that ATP promotes progenitor cell proliferation in this stem cell rich regions. Previous studies have shown that the extracellular nucleotide-hydrolyzing enzyme NTPDase2 is highly expressed by adult neural stem and progenitor cells of the SVZ and the rostral migratory stream (RMS), the hippocampal SGL, and the third ventricle. NTPDase2 preferentially hydrolyzes extracellular nucleoside triphosphates (NTPs) and, to a lower extent, diphosphates, thus modulating their effect on nearby nucleotide receptors. Deletion of the enzyme increases extracellular NTP concentrations, and might indicate roles of purinergic signaling in adult neurogenesis. As shown by enzyme histochemistry, genetic deletion of NTPDase2 essentially eliminates ATPase activity in neurogenic niches but does not affect protein expression levels and activity of other ectonucleotidases. Lack of NTPDase2 leads to expansion of the hippocampal stem cell pool as well as of the inter-mediate progenitor type-2 cells. Cell expansion is lost at around type-3 stage, paralleled by increased labeling for caspase-3, indicating increased apoptosis, and decreased levels in CREB phosphorylation in doublecortin-expressing cells, diminishing survival in this cell population. In line with increased cell death, P2Y12 receptor-expressing microglia is enriched at the hilus orientated side of the granule cell layer. These data strongly suggest that NTPDase2 functions as central homeostatic regulator of nucleotide-mediated neural progenitor cell proliferation and expansion in the adult brain by balancing extracellular nucleotide concentrations and activation of purinergic receptors.
In order to further characterize the role of purinergic signaling in adult neurogenesis, the ADP-sensitive P2Y13 receptor was identified as a potential candidate whose activation might inhibit neurogenesis in the hippocampal dentate gyrus and the newly identified neurogenic niche at the third ventricle. Deletion of P2ry13 increased progenitor cell proliferation and long-term progenitor survival as well as new neuron formation in the hippocampal neurogenic niche. This was further paralleled by increased thickening of the granule cell layer, CREB phosphorylation, and expression of the neuronal activity marker c-Fos. Increased progenitor cell proliferation and progenitor survival persist in aged P2ry13 knockout animals. However, in the ventral dentate gyrus proliferation and expansion levels of progenitor cells did not differ significantly from the wild type. This study strongly supports the notion that extracellular nucleotides significantly contribute to the control of adult neurogenesis in the dentate gyrus in situ. Data in this work suggest that activation of the P2Y13 receptor dampens progenitor cell proliferation, new neuron formation, and neuronal activity. In contrast to several in vitro studies and studies in the SVZ in situ, a contribution of the ATP/ADP-sensitive P2Y1 receptor could not be confirmed in the dentate gyrus in vivo.
To unravel implications of purinergic signaling and P2Y13 receptor action in the control of adult hypothalamic neurogenesis a pilot study was performed. Mice null for P2ry13 revealed increased progenitor cell proliferation at the third ventricle as well as long-term progeny survival and new neuron formation in the hypothalamus. In contrast to results obtained in the dentate gyrus expression of the neuronal activity marker c-Fos was significantly decreased in hypothalamic nuclei, indicating increased inhibition of appetite-regulating neuronal circuits by surplus neurons in knockout animals. These data provide first evidence that extracellular nucleotide signaling contributes to the control of adult hypothalamic neurogenesis in situ. Activation of the P2Y13 receptor inhibits progenitor cell proliferation, long-term survival and neuron formation and therefore controls inhibition of appetite-regulating circuits in the adult rodent hypothalamus.
Juvenile neuronal ceroid-lipofuscinosis (JNCL) is a rare lysosomal storage disease in children with lethal outcome and no therapy. The origin of JNCL has been traced to autosomal recessive mutations in the CLN3 gene, and ~85% of the JNCL patients harbor a 1.02 kb deletion that removes the exons 7 and 8 and the surrounding intronic DNA (CLN3Δex7/8). So far, structure, function and localization of the CLN3 protein remain elusive. However, there is strong evidence that CLN3 modulates a process or condition that is essential in many cellular pathways. Lipid metabolism and antero-/retrograde transport, two mechanisms CLN3 was previously implicated in, fulfill these requirements. Notably, also a bioactive group of glycosphingolipids referred to as gangliosides is tightly interrelated with these functions. Furthermore, a-series gangliosides have been shown to be involved in the development and sustenance of the brain, where they are essential for neurite outgrowth and cell survival. Defects in ganglioside metabolism were shown to play a crucial role in many lysosomal storage disorders. However, the contribution of gangliosides to NCL pathology is largely unknown.
The present study analyzed central enzymes and metabolites of the a-series ganglioside pathway in a JNCL cell model. The core finding was, thereby, the reduced amount of the neuroprotective ganglioside GM1 in homozygous CbCln3Δex7/8 cells. This was caused by the enhanced action of the GM1-degrading multimeric enzyme complex and in particular, by the upregulation of protein levels and increased enzyme activity of β-galactosidase (Glb1).
Improved binding of Glb1 to substrate-carrying membranes was provided by an increase in LBPA levels. In combination with other smaller alterations in the ganglioside pattern, a shift towards less complex gangliosides became present. The resulting loss of neuroprotection may be the reason for the multifocal pathology in homozygous CbCln3Δex7/8 cells.
The second part of the present study investigated the cellular mechanisms behind the altered ganglioside profile with regard to the potential role of CLN3. Here, the anterograde transport of GM1 to the plasma membrane presented a positive correlation with the amount of full-length CLN3. In case of the truncated protein this correlation was missing, resulting in reduced PM staining with CTxB-FITC. However, transfection of full-length CLN3 in these cells restored the CTxB-FITC intensity. Based on the neuroprotective role of GM1, the corresponding increase in GM1 levels may be the cause for the restoration effects observed in previous studies using full-length CLN3. Hence, administration of GM1 was expected to improve cell viability of homozygous CbCln3Δex7/8 cells and beyond that to rescue potentially some disease phenotypes. However, no effect could be observed. The reason for this may be reduced caveolar uptake and the mislocalization of ganglioside GM1 to the trans-Golgi network (TGN) and redirection towards degradative compartments.
Both are in line with the idea of an impaired endocytic flux in CLN3 deficiency. The observed localization of CLN3 in the TGN suggests a potential role for CLN3 in the lipid sorting machinery, subsequently altering membrane composition and its regulatory functions. The resulting imbalance may affect many of the cellular processes impaired in JNCL.
In this thesis, we study some features of the quantum chromodynamics (QCD) phase diagram at purely imaginary chemical potential using lattice techniques. This is one of the possible methodologies to get insights about the situation at finite density, where the sign problem prevents direct investigations from first principles.
We focus, in particular, on the Roberge-Weiss plane, where the phase structure with two degenerate flavours is studied both in the light and in the heavy quark mass limit. On the lattice, any result is affected by cut-off effects and so are the positions of the two tricritical points m_{tric}^{1,2} separating the second-order intermediate mass region from the first-order triple light and heavy mass regions. Therefore, changing the lattice spacing 'a', the values of m_{tric}^1 and m_{tric}^2 will change. In order to find their position in the continuum limit – i.e. for 'a' going to 0 – they have to be located on finer and finer lattices. Typically, in lattice QCD (LQCD) simulations, the temperature T is tuned through the bare coupling β, on which 'a' depends, while keeping Nt fixed. Hence, it is common to implicitly refer to how fine the lattice is just mentioning its temporal extent.
Using both Wilson and staggered fermions, we simulate Nf=2 QCD on Nt=6 lattices, varying the quark bare mass from the chiral (m_{u,d} going to 0) to the quenched (m_{u,d} going to infinity) limit. For each quark mass, a thorough finite scaling analysis is carried out, taking advantage of two different but consistent methods. In this way we identify the order of the phase transition locating, then, the position of the tricritical points. In order to convert our measurements to physical units we fix the scale measuring the lattice spacing as well as the pion mass corresponding to the quark bare mass used. This allows a comparison between different discretisation, getting a first idea of how serious are cut-off effects.
To be able to make a comparison between two different discretisations, we added an RHMC algorithm with staggered fermions to the CL2QCD software, a GPU code based on OpenCL, which we released in 2014. A considerable part of our work has been invested in ameliorating and optimising CL2QCD, as well as in developing new analysis tools regularly used next to it. Just to mention one, the multiple histogram method has been implemented in a completely general way and we took advantage of it in order to obtain more precise results. Finally, in order to efficiently handle and monitor the hundreds of simulations that are typically concurrently run in finite temperature LQCD, a completely new Bash library of tools has been developed. We plan to release it as a byproduct of CL2QCD in the near future.
In this thesis, the production of charged kaons and Φ mesons in Au+Au collisions at sqrt sAuAu = 2.4 GeV is studied. At this energy, all particles carrying open and hidden strangeness are produced below their respective free nucleon-nucleon threshold with the corresponding so-called excess energies: sqrt sK+ exc = -0.15 GeV, sqrt sK- exc = -0.46 GeV, sqrt sΦ exc = -0.49 GeVGeV. As a consequence, the production cross sections are very sensitive to medium effects like momentum distributions, two- or multistep collisions, and modification of the in-medium spectral distribution of the produced states [1]. K+ and K- mesons exhibit different properties in baryon dominated matter, since only K- can be resonantly absorbed by nucleons. Although strangeness exchange reactions have been proposed to be the dominant channel for K- production in the analyzed energy regime, the production yield and kinematic distributions could also be explained in smaller systems based on statistical hadronization model fits to the measured particle yields, including a canonical strangeness suppression radius RC, and taking the Φ feed-down to kaons into account [2, 3]. For the first time in central Au+Au collisions at such low energies, it is possible to reconstruct and do a multi differential analysis of K- and Φ mesons. In principle, this should be the ideal environment for strangeness exchange reactions to occur, as the particles are produced deeply sub-threshold in a large and long-living system. Therefore, it is the ultimate test to differentiate between the different sources for K- production in HIC.
In total 7.3x10exp9 of the 40% most central Au(1.23 GeV per nucleon)+Au collisions are analyzed. The data has been recorded with the High Acceptance DiElectron Spectrometer HADES located at Helmholtzzentrum für Schwerionenforschung GSI in April/May 2012. A substantially improved reconstruction method has been employed to reconstruct the hadrons with high purity in a wide phase space region.
The estimated particle multiplicities follow a clear hierarchy of the excess energy: 41.5 ± 2.1|sys protons at mid-rapidity per unit in rapidity, 11.1 ± 0.6|sys ± 0.4|extrapol π-, (3.01 ± 0.03|stat ± 0.15|sys ± 0.30|extrapól) x10 exp -2 K+, (1.94 ± 0.09|stat ± 0.10|sys ± 0.10|extrapol)x10 exp -4 K- and (0.99 ± 0.24|stat ± 0.10|sys ± 0.05|extrapol)x10 exp -4 Φ per event. The multiplicities of the strange hadrons increase more than linear with the mean number of participating nucleons hAparti, supporting the assumption that the necessary energy to overcome the elementary production threshold is accumulated in multi-particle interactions. Transport models predict such an increase, but are overestimating the measured particle yield and are not able to describe the kinematic distributions of K+ mesons perfectly. However, the best description is given by the IQMD model with a density dependent kaonnucleon potential of 40 MeV at nuclear ground state density.
The K-=K+ multiplicity ratio is constant as a function of centrality and follows with (6.45 ± 0.77)x10 exp -3 the trend of increasing with beam energy indicated from previous experiments [4]. The effective temperature of K- TK+eff = (84 ± 6) MeV is found to be systematically lower than the one of K+ TK+eff = (104 ± 1) MeV, which has also been observed by the other experiments.
The Φ=K- ratio is with a value of 0.52 ± 0.16 higher than the one obtained at higher center-of-mass energies and smaller systems. This behavior is predicted from a tuned version of the UrQMD transport model [5], when including higher mass baryonic resonances which can decay into Φ mesons and from statistical hadronization models when suppressing open strangeness canonically. The found ratio is constant as a function of centrality and results with a branching ratio of 48.9%, that ~ 25% of all measured K- originate from Φ feed-down decays. A two component PLUTO simulation, consisting of a pure thermal and a K- contribution originating from Φ decays, can fully explain the observed lower effective temperature in comparison to K+ and the shape of the measured rapidity distribution of K-. As a result, we find no indication for strangeness exchange reactions being the dominant mechanism for K- production in the SIS18 energy regime, if taking the contribution from Φ feed-down decays into account.
The hadron yields for the 20% most central collisions can be described by a statistical hadronization model fit with the chemical freeze-out temperature of Tchem = (68 ± 2) MeV and baryochemical potential of μB = (883 ± 25) MeV, which is higher than expected from previous parameterizations. The analysis of the transverse mass spectra of protons indicate a kinetic freeze-out temperature of Tkin = (70 ± 4) MeV and radial flow velocity of βr = 0.43 ± 0.01, which is in agreement with the parameters obtained from the linear dependence of the effective temperatures on the particle mass Tkin = (71.5 ± 4.2) MeV and βr = 0.28 ± 0.09.