Search for dissertations about: "three-terminal"
Showing result 1 - 5 of 24 swedish dissertations containing the word three-terminal.
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1. Multiple Andreev reflections and nonequilibrium Josephson effect in three-terminal superconducting junctions
Abstract : .... READ MORE
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2. Modelling of Quantum Transport in Nanostructures
Abstract : In this thesis, theoretical studies of the transport properties of three nanoscale systems: one-dimensional (1D) quantum wires (QWRs), zero-dimensional (0D), laterally confined, double-barrier resonant tunnelling structures (DBRTSs) and three-terminal ballistic junctions (TBJs), have been performed. In the first part of the thesis, an overview of the realization and properties of such systems is given along with a description of modelling tools used in the calculations. READ MORE
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3. Quantum and Ballistic Nanodevices
Abstract : In this thesis, electron transport in quantum and ballistic devices was studied. The devices studied here were quantum wires, planar quantum dots, ballistic rectifiers, artificial functional materials, and three-terminal ballistic junctions. The possible application of such devices in the future nanoelectronics was also investigated. READ MORE
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4. Nanoelectronic Devices Based on Low-Dimensional Semiconductor Structures
Abstract : The present thesis reports on results from the fabrication technology development and the corresponding electrical transport measurements of low-dimensional semiconductor structures. The focus of the work has been directed towards two parts: the ballistic transport in nanostructure devices at room temperature, and the development of a charge-sensing technique for quantum dots (QD) in nanowires. READ MORE
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5. Technology and studies of electron transport in InAs nanowire junctions
Abstract : The topic of this thesis is technology and experimental studies of electron transport in Indium Arsenide (InAs) nanowires and InAs nanowire junctions. The aim of this work has been fabrication of nanoelectronic devices which have possibilities for future nanoelectronics. READ MORE