Universität Stuttgart

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Publication Type: search.filters.UBSTyp.DissertationSubject: search.filters.subject.540Subject: search.filters.subject.570Subject: search.filters.subject.530

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    ItemOpen Access
    Gold nanoparticle-mediated DNA origami nanoarchitectures
    (2024) Peil, Andreas; Na Liu, Laura (Prof. Dr.)
    Since its origin in the 1980s, DNA (deoxyribonucleic acid) nanotechnology has established itself as a captivating nanofabrication technique with ever increasing impact that combines aspects from physics, chemistry, and biology to construct artificial nanosystems by means of molecular self assembly. Within the field of DNA nanotechnology, the DNA origami technique represents one of the most versatile fabrication tools to craft functional two-dimensional (2D) and three-dimensional (3D) nanostructures from the bottom up. These structures offer precisely tailored geometries along with programmable functions, featuring positional addressability with sub-5 nm resolution and exceptional spatiotemporal accuracy. This thesis discusses strategies to employ the DNA origami technique to assemble intricate hybrid nanosystems with synergistically integrated gold nanoparticles (AuNPs). The AuNPs take over different roles; they grant (i) structural and (ii) functional features and enable the (iii) optical monitoring of the systems. This approach allows the fabrication of nanostructures piece by piece to explore their structural and functional properties at the nanoscale in detail. The first publication covers different strategies for the hierarchical assembly of topological DNA origami structures using a AuNP-templated self-assembly approach. The assembly of [2], [3], and [4]catenanes with interconnecting AuNPs is elucidated. The AuNPs can be controllably released to disconnect the individual rings, leaving only the mechanical bond of the catenane chain. In the second publication, a dynamic AuNP-DNA origami gear system is presented that is designed to emulate a planetary gearset with precise spatiotemporal control over its rotation dynamics. The AuNPs serve three crucial tasks. They (i) structurally link the origami ring modules, (ii) mediate the rotation and (iii) enable the real time optical tracking of the rotation via fluorescence spectroscopy. The system enables tightly orchestrated and programmable bidirectional rotations. In the third publication, reconfigurable chiral metastructures comprising multiple plasmonic particles that are accurately positioned in a helical manner around a DNA origami template are discussed. The implementation of a DNA ‘swingarm strategy’ enables the simultaneous and efficient relocation of multiple closely spaced AuNPs over large distances to precisely tune the chiroptical response of the system. The presented publications illustrate the beneficial synergies between DNA origami systems and rationally integrated AuNPs with the aim to advance and expand the application spectrum of these hybrid nanosystems within their scientific disciplines.
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    ItemOpen Access
    Electronic transport properties of DNA sensing nanopores : insight from quantum mechanical simulations
    (2017) Sivaraman, Ganesh; Fyta, Maria (Jun.-Prof. Dr.)
    The translocation of DNA through nanopores is an intensively studied field as it can lead to a new perspective in DNA sequencing. During this process the DNA is electrophoretically driven through a nanoscale hole in a membrane, and use different sensing schemes to read out the sequence. Within the scope of nanopore sequencing two important sensing schemes relevant to this thesis are: 1.) Tunneling sequencers based on solid state nanopores embedded with gold electrodes 2.) 2D materials beyond graphene For scheme 1, an obvious improvement is to coat the gold electrode with molecules that have high conductance and can form instantaneous hydrogen bond bridges with the translocating polynucleotide thereby improving the transverse current signal. The molecule that we propose is the so called diamondoid which are diamond caged molecules with hydrogen termination. Before applying such a molecule to a nanopore electrode set up, one would like to understand their interaction with DNA and its nucleobases. For this purpose, hydrogen bonded complexes formed between nitrogen doped derivatives of smallest diamondoids (i.e. adamantane derivatives) and nucleobases were investigated using dispersion corrected density functional theory (DFT). Mutated and methylated nucleobases are also taken into consideration in these investigations. DFT calculations revealed that hydrogen bonds are of moderate strength. In addition, starting from the DFT predicted hydrogen bonding configuration for each complex, rotations, and translations along a reference axis was performed to capture variations in the interaction energies along the donor-acceptor groups of the hydrogen bonds. The electronic density of states analysis for the hydrogen bonded complexes revealed distinguishable signatures for each nucleobase, thereby showing the suitability for application in electrodes functionalised with such probe molecules. In the next step, an adamantane derivative is placed on one of the electrode and nucleotides are introduced in such a way that nucleobases form hydrogen bonds with the of the nitrogen group of the adamantane derivatives. Electronic transport calculations were performed for gold electrodes functionalised with 3 different adamantane derivatives. Four pristine nucleotides, one mutated, and one methylated nucleotides were considered. Analysis of the transmission spectra reveal that each of the nucleotides has a unique resonance peak far below the Fermi level. We have also proposed a gating voltage window to sample the resonance peaks of the nucleotide so that they can be distinguished from each other. An alternative to tunneling sequencers would be to use nanopores built in to ultra thin metallic nanoribbons such as graphene. The sequence can be read out from the in-plane current modulation resulting from the local field effect of the translocating nucleotides in the vicinity of the metallic pore edges. But the hydrophobicity of graphene makes it a difficult candidate in aqueous environment. Hence in scheme 2, the aim is to model an ultra thin material that can rectify the hydrophobicity of graphene and can be a very good candidate for current modulation sequencing. Ultra thin MoS2 (2H) monolayer exist as direct band gap semiconductor. Nanopores based on 2H phases have been reported in the literature and are not hydrophobic. By means of chemical exfoliation of the 2H phase, a meta stable 1T phase of MoS2 has also been synthesized by various experimental groups. The 1T phase of MoS2 is metallic. The aim of this thesis is to model a nano-biosensor template based on a hybrid MoS2 monolayer made up of a metallic (1T) phase sandwiched between semiconducting (2H) phase. The sensor that we propose, should have only metallic nanopore edges. As a first step, we have modeled the semiconductor-metal interface, and compared them with experiments. Then an investigation to understand the influence of the increase of the metallic unit on the electronic properties is performed. Since, point defects are highly relevant to electrochemical pore growth, a point sulfur defect analysis is provided to ascertain the weakest point in the sheet. Finally to understand the effect of the interface electronic transport calculations are performed. The transmission spectra reveals a clear asymmetry in the current flow across the interface by means of gating. In the end, the relevance of such a hybrid MoS2 material for nanopore sequencing is discussed.
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    ItemOpen Access
    Scale-up of gas fermentations : modelling tools for risk minimisation
    (2020) Siebler, Flora
    The reduction of greenhouse gas emissions is a global endeavour supported by society, politics and industry. In recent years, circular economy, reducing the exploitation of fossil energy sources, have increased the demand for new solutions when producing commodities and fine chemicals. Caboxydotrophic fermentations with acetogenic bacteria are potential processes in order to reach these goals. They convert gaseous substrates such as CO, and CO2/H2 mixtures. However, gases as sole substrate are rather challenging, not only in small lab-scales but especially in large-scale. Transferring an efficient fermentation process from experimental to industrial scales often results in unpredictable performance losses. This study presents an in silico concept minimising possible risks in gas fermentations up-scaling. First, the economical feasibility of various fermentation methods is investigated. Then, two computational tools are presented using Clostridium ljungdahlii as model organism and synthesis gas as substrate in a 125 m3 bubble column reactor. The combination of economical investigation with modelling tools show high potential for successful scale-up of gas fermentations. With this concept feasibility, reactor design, operation mode and general risk minimisation can be analysed and specified.