Global ETD Search

111	A theoretical perspective on photoinduced reactions - based on quantum chemical models and non-adiabatic molecular dynamics. Das, Sambit January 2023 (has links) The broad range of applications for photochemical reactions is the result of light-matter interaction at the electronic level. The diverse application of photochemistry in various fields, including photovoltaic materials, molecular switches, and biological systems are due to electronic and structural transformations induced by photoexcitation as well as molecular alteration due to electron and charge transfer. An improved understanding of these photochemical events is dependent on the fundamental theoretical evaluation, to model and analyze the ultrafast processes. The studies discussed in this thesis explore such theoretical implementation in two different frontiers. In the first study, dynamic simulations are performed to model the light-induced bond dissociation of phenyl azide. The surface hopping formalism, implemented under the semiclassical molecular dynamics approach helped in tracing the time evolution of the electronic and structural levels, involved in the photodissociation. In the second study, the time-dependent density functional theory has been applied to generate XA spectra of imidazole solutions. The theoretical assessments support experimental measurements and provide more insight into the core excitations and structural influence on the absorption spectra. / Fotokemiska reaktioner styrs av växelverkan mellan ljus of materia på en elektronisk nivå. I olika fält finns det vitt skilda tillämpningarna av fotokemi. Dessa inkluderar ljusinducerade processer i solceller, molekylära strömbrytare, och biologiska system. Reaktionerna beror av elektroniska och strukturella transformationer som induceras av fotoexcitationen, och kan ge upphov till energi- och laddningsöverföring. För att få utökad förståelse av fotokemiska reaktioner behövs grundläggande teoretiska studier där ultrasnabba processer modelleras och analyseras i jämförelse med experiment. Undersökningar som presenteras i denna avhandling använder sig att teoretiska modeller i två olika områden av fotokemi. I den första studien har vi genomfört dynamiska simuleringar för att modellera ljusinducerad dissociation av fenylazid. Vi have använt en semi-klassisk approximation med hopp mellan olika elektroniska tillstånd vilket gör det möjligt att följa utvecklingen i elektroniska och geometriska frihetsgrader under fotodissociationen. I den andra studien har tidsberoende täthetsfunktionalteori använts för att simulera röntgenabsorptionsspektrum för imidazol i lösning. Genom att utvärdera olika geometriska modeller med teoretiska beräkningar kan vi berika tolkningen av experimentella mätningar, och även få detaljerat insikt i innerskalsexcitationer och hur geometrin påverka röntgenspektrum. Non-adiabatic dynamics Molecular dynamics Surface hopping TDDFT X-ray absorption spectroscopy Theoretical Chemistry Teoretisk kemi Atom and Molecular Physics and Optics Atom- och molekylfysik och optik
112	Studies of Electronic Transport in Novel Smectic and Discotic Liquid Crystalline Organic Semiconductors Naresh, Shakya Man 12 November 2010 (has links) No description available. Physics organic semiconductors calamitic and discotic liquid crystals electronic transport mobility ordered and disordered medium smectic mesophase polaron laser time of flight band and hopping conductions freely suspended film pyridine thiophene
113	Complexities in Nonadiabatic Dynamics of Small Molecular Anions Opoku-Agyeman, Bernice 24 May 2018 (has links) No description available. Chemistry Physical Chemistry Potential energy surfaces Excitation energies Wave functions Ground states Excited states Photodissociation Surface Hopping Semi-classical energy distribution argon solvation charge transfer nonadiabatic
114	Run-Time Active Leakage Control Mechanism based on a Light Threshold Voltage Hopping Technique (LITHE) Ravi, Ajaay 26 September 2011 (has links) No description available. Computer Engineering Leakage Power Reduction Run-Time Active Leakage Control Threshold Voltage Hopping Substrate Biasing LITHE Steady state leakage current reduction
115	Growth and anisotropic transport properties of self-assembled InAs nanostructures in InP Bierwagen, Oliver 22 June 2007 (has links) Selbstorganisierte InAs Nanostrukturen in InP, wie Quantendrähte, Quantenpunkte, und Quantengräben als Referenz, werden bezüglich ihres Wachstums, ihrer Struktur, optischen Eigenschaften und Transporteigenschaften untersucht. Das Stranski-Krastanov Wachstum der Nanostrukturen auf exakt orientiertem und vizinalem InP(001) wird mittels Gasquellen-Molekularstrahlepitaxie untersucht. Ich zeige, dass die Missorientierung des vizinalen InP, weitestgehend unabhängig von den Wachstumsparametern, den Nanostrukturtyp definiert. Optische Polarisation der Interbandübergänge (im 1.55 Mikrometer Bereich) aufgrund des Nanostrukturtyps wird mittels Photolumineszenz- und Transmissionsspektroskopie wird nachgewiesen. Die experimentell unaufwändige 4-Kontakt van der Pauw Hall Messung wird erweitert, um anisotrope Transporteigenschaften zu bestimmen. Der Ladungstägertransport in einer Schicht dicht gepackter, lateral gekoppelter InAs Nanostrukturen ist stark anisotrop mit der Hochbeweglichkeitsrichtung [-110], was parallel zur Richtung der Quantendrähte ist. Die maximalen Anisotropien übersteigen 30 für Elektronen und 100 für Löcher. Die extreme Anisotropie im Falle der Löcher basiert auf diffusem Transport in der [-110], und Hoppingtransport in der [110] direction. Die Elektronenbeweglichkeit bei niedrigen Temperaturen wird duch Grenzflächenrauhigkeitsstreuung in der [110] direction, und Streuung an entfernten Störstellen in der [-110] dominiert. Im Kontext gekoppelter Nanostrukturen, zeige ich, dass die Transportanisotropie auf anisotroper Tunnelkopplung zwischen benachbarten Nanostrukturen beruht, und weniger durch die Form der Nanostruktur bestimmt wird. Transport im Quanten-Hall Regime, und die Schwache Lokalisierung werden untersucht. Ein neuartiges Baulelement basierend auf Gate-konrollierter Transportanisotropie wird vorgeschlagen. Es wird gezeigt, dass modulationsdotierte InAs Quantendrähte für eine Implementierung des Bauelements geeignet sind. / Self-assembled InAs nanostructures in InP, comprising quantum wires, quantum dots, and quantum wells as reference, are studied in terms of their formation, structural properties, optical properties, and anisotropic transport properties. The Stranski-Krastanov growth of InAs nanostructures is studied by gas-source molecular beam epitaxy on both nominally oriented and vicinal InP(001). I demonstrate that the off-cut direction of vicinal substrates - largely independent of growth conditions - determines the nanostructure type. Optical polarization of the interband transitions (in the 1.55 micron wavelength range) arising from the nanostructure type is demonstrated by photoluminescence and transmission spectroscopy. The experimentally convenient four-contact van der Pauw Hall measurement is extended to yield the anisotropic transport properties. The in-plane transport in large ensembles of closely spaced, laterally coupled InAs nanostructures is highly anisotropic with the high-mobility direction [-110], which is parallel to the direction of the quantum wires. The maximum anisotropies exceed 30 for electrons, and 100 for holes. The extreme anisotropy for holes is due to diffusive transport in the [-110], and hopping transport in the [110] direction. The principal electron mobilities at low temperature are dominated by interface roughness scattering in the [110] direction, and by remote impurity scattering in the [-110] direction. In the context of coupled nanostructure, I demonstrate that the transport anisotropy results from directionally anisotropic tunnel coupling between adjacent nanostructures rather than from the nanostructure shape anisotropy. The Quantum-Hall regime, and the weak-localization contribution to conductivity is studied. A novel 5-terminal electronic switching device based on gate-controlled transport anisotropy is proposed. Modulation-doped InAs/InP quantum wires are demonstrated to be a candidate for implementation of the device. Transmission InAs auf InP MBE Selbstorganisation Nanostruktur Quantengraben Quantendraht Quantenpunkt Transport Anisotropie Kopplung Streuung Tunneln Hopping Transport van der Pauw Photolumineszenz Absorption Polarisation InAs on InP MBE self-assembled growth nanostructure quantum well quantum wire quantum dot transport anisotropy coupling scattering tunneling hopping van der Pauw photoluminescence transmission absorption polarization 530 Physik 29 Physik, Astronomie ddc:530
116	Electrically Conductive Low Dimensional Nanostructures: Synthesis, Characterisation and Application Bocharova, Vera 05 January 2009 (has links) (PDF) Miniaturization has become a driving force in different areas of technology including microelectronics, sensoric- and bio-technologies and in fundamental science. Because of the well-known limitations of conventional lithographic methods, newly emerging bottom-up approach, utilizing self-assembly of various nanoobjects including single polymer molecules and carbon nanotubes constitutes a very promising alternative for fabrication of ultimately small devices. Carbon nanotubes are attractive materials for nanotechnology and hold much promise to revolutionize fundamental science in a investigation of phenomena, associated with the nanometer–sized objects.It was found in this work that grafted chains of poly(2-vinylpyridine) form a shell covering the carbon nanotubes that makes them dispersible in organic solvents and in acidic water (CNTs-g-P2VP).The positively charged poly(2-vinylpyridine) shell is responsible for the selective deposition of carbon nanotubes onto oppositely charged surfaces. It was established that the deposition CNTs-g-P2VP from aqueous dispersions at low pH is an effective method to prepare ultra-thin films with a tunable density of carbon nanotubes.It was shown that poly(2-vinylpyridine) grafted to carbon nanotubes is a universal support for the immobilization of various nanoclusters at the carbon nanotube's surface. Prussian Blue nanoparticles were selectively attached to the surface of CNTs-g-P2VP.Conducting polymer nanowires are another very promising kind of nanomaterials that could be also suitable for applications in nanodevices and nanosensors. In this work was developed a simple method to control the conformation and orientation of single adsorbed polyelectrolyte molecules by co-deposition with octylamine. A simple chemical route to conductive polypyrrole nanowires by the grafting of polypyrrole from molecules of polystyrensulfonic acid was developed. The dc conductivity of individual polypyrrole nanowires approaches the conductivity of polypyrole in bulk.The conductivity can be described using variable-range hopping model. Carbon nanotubes poly(2-vinylpyridine) Prussian Blue percolation theory conductive nanowire polypyrrole template-based method octyle amine polyelectrolyte Atomic Force Microscopy conductivity variable-range hopping model polystyrensulfonic aci Carbon Nanoröhren Poly(2-vinylpyridine) Berliner Blau Leitfähigkeit Percolation Theorie Leitfähigenanodrähte Polypyrole Nanostrukturen Template Methode Octyle Amine Rasterkraftmikroskopie Polyelektrolyte Variable-range hopping model Polystyre ddc:540 rvk:VE 9857
117	Electrically Conductive Low Dimensional Nanostructures: Synthesis, Characterisation and Application Bocharova, Vera 16 December 2008 (has links) Miniaturization has become a driving force in different areas of technology including microelectronics, sensoric- and bio-technologies and in fundamental science. Because of the well-known limitations of conventional lithographic methods, newly emerging bottom-up approach, utilizing self-assembly of various nanoobjects including single polymer molecules and carbon nanotubes constitutes a very promising alternative for fabrication of ultimately small devices. Carbon nanotubes are attractive materials for nanotechnology and hold much promise to revolutionize fundamental science in a investigation of phenomena, associated with the nanometer–sized objects.It was found in this work that grafted chains of poly(2-vinylpyridine) form a shell covering the carbon nanotubes that makes them dispersible in organic solvents and in acidic water (CNTs-g-P2VP).The positively charged poly(2-vinylpyridine) shell is responsible for the selective deposition of carbon nanotubes onto oppositely charged surfaces. It was established that the deposition CNTs-g-P2VP from aqueous dispersions at low pH is an effective method to prepare ultra-thin films with a tunable density of carbon nanotubes.It was shown that poly(2-vinylpyridine) grafted to carbon nanotubes is a universal support for the immobilization of various nanoclusters at the carbon nanotube's surface. Prussian Blue nanoparticles were selectively attached to the surface of CNTs-g-P2VP.Conducting polymer nanowires are another very promising kind of nanomaterials that could be also suitable for applications in nanodevices and nanosensors. In this work was developed a simple method to control the conformation and orientation of single adsorbed polyelectrolyte molecules by co-deposition with octylamine. A simple chemical route to conductive polypyrrole nanowires by the grafting of polypyrrole from molecules of polystyrensulfonic acid was developed. The dc conductivity of individual polypyrrole nanowires approaches the conductivity of polypyrole in bulk.The conductivity can be described using variable-range hopping model. info:eu-repo/classification/ddc/540 ddc:540
118	Electrical Conduction Mechanisms in the Disordered Material System P-type Hydrogenated Amorphous Silicon Shrestha, Kiran (Engineer) 12 1900 (has links) The electrical and optical properties of boron doped hydrogenated amorphous silicon thin films (a-Si) were investigated to determine the effect of boron and hydrogen incorporation on carrier transport. The a-Si thin films were grown by plasma enhanced chemical vapor deposition (PECVD) at various boron concentrations, hydrogen dilutions, and at differing growth temperatures. The temperature dependent conductivity generally follows the hopping conduction model. Above a critical temperature, the dominant conduction mechanism is Mott variable range hopping conductivity (M-VRH), where p = ¼, and the carrier hopping depends on energy. However, at lower temperatures, the coulomb interaction between charge carriers becomes important and Efros-Shklosvkii variable hopping (ES-VRH) conduction, where p=1/2, must be included to describe the total conductivity. To correlate changes in electrical conductivity to changes in the local crystalline order, the transverse optical (TO) and transverse acoustic (TA) modes of the Raman spectra were studied to relate changes in short- and mid-range order to the effects of growth temperature, boron, and hydrogen incorporation. With an increase of hydrogen and/or growth temperature, both short and mid-range order improve, whereas the addition of boron results in the degradation of short range order. It is seen that there is a direct correlation between the electrical conductivity and changes in the short and mid-range order resulting from the passivation of defects by hydrogen and the creation of trap states by boron. This work was done under the ARO grant W911NF-10-1-0410, William W. Clark Program Manager. The samples were provided by L-3 Communications. Electrical conductivity variable range hopping raman spectroscopy short and mid-range order raman electrical correlation Amorphous substances. Silicon. Thin films -- Electric properties. Thin films -- Optical properties. Boron. Hydrogen. Electric conductivity.
119	Accelerated sampling of energy landscapes Mantell, Rosemary Genevieve January 2017 (has links) In this project, various computational energy landscape methods were accelerated using graphics processing units (GPUs). Basin-hopping global optimisation was treated using a version of the limited-memory BFGS algorithm adapted for CUDA, in combination with GPU-acceleration of the potential calculation. The Lennard-Jones potential was implemented using CUDA, and an interface to the GPU-accelerated AMBER potential was constructed. These results were then extended to form the basis of a GPU-accelerated version of hybrid eigenvector-following. The doubly-nudged elastic band method was also accelerated using an interface to the potential calculation on GPU. Additionally, a local rigid body framework was adapted for GPU hardware. Tests were performed for eight biomolecules represented using the AMBER potential, ranging in size from 81 to 22\,811 atoms, and the effects of minimiser history size and local rigidification on the overall efficiency were analysed. Improvements relative to CPU performance of up to two orders of magnitude were obtained for the largest systems. These methods have been successfully applied to both biological systems and atomic clusters. An existing interface between a code for free energy basin-hopping and the SuiteSparse package for sparse Cholesky factorisation was refined, validated and tested. Tests were performed for both Lennard-Jones clusters and selected biomolecules represented using the AMBER potential. Significant acceleration of the vibrational frequency calculations was achieved, with negligible loss of accuracy, relative to the standard diagonalisation procedure. For the larger systems, exploiting sparsity reduces the computational cost by factors of 10 to 30. The acceleration of these computational energy landscape methods opens up the possibility of investigating much larger and more complex systems than previously accessible. A wide array of new applications are now computationally feasible. 660.0285
120	An Investigation Of The Ferromagnetic Insulating State Of Manganites Jain, Himanshu 07 1900 (has links) Electrical conductance in the ferromagnetic insulating (FMI) phase of manganites has been experimentally investigated. The investigations were performed on single crystals of compositions La0.82Ca0.18MnO3 and Nd0.7Pb0.3MnO3. The nature of electrical conductance is determined to be Shklovskii–Efros variable range hopping (SE–VRH). Further, at high bias levels, non–linear conductance (NLC) is observed. A “hot electron” model, that quantitatively explains the bias and temperature dependence of the NLC, consistent with the SE–VRH nature of electrical conductance, is presented. The limits of validity of the model are discussed. Manganites - Ferromagnetic Insulation Manganites Hole Doped Manganites Ferromagnetic and Insulating Manganites Colossal Electroresistance Colossal Magnetoresistance Non-linear Conductance Manganites - Electrical Conductance Ferromagnetic Insulation Ferromagnetic Insulating (FMI) Magnetism

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