Welcome to Nano-Electronics (Mesoscopic Physics) at the University of Basel
From now on I'll List Links for Theses Collection rather than single thesis. This should give you more freedom to select proper titles. My advice is to store all these materials in your backup media; you may not find these materials in future
Sincerely, Dr. Saad B. H. Farid
From now on I'll List Links for Theses Collection rather than single thesis. This should give you more freedom to select proper titles. My advice is to store all these materials in your backup media; you may not find these materials in future
Sincerely, Dr. Saad B. H. Farid
Introducing the research group
Link
http://www.nanoelectronics.ch/publications/theses.php
Really Good Luck
We explore the electrical properties of devices and circuits with dimensions ranging from several micrometer (one thousands of a millimeter) down to one nanometer. At these dimensions quantum phenomena start play a dominat role. Electrons become extented objects with a wave character. Just as ordinary waves (e.g. water waves), electrons can interfere forming standing wave patterns. Such interference patterns are a direct manifestation of quantum behavior which can be visualized, for example with scanning-probe microscopes or by measuring the electrical resistance as a function of an external control parameter, such as the magnetic field.
Quantum interference is the basis for the formation of most of our matter in daily life. The reason that atoms bind together to form molecules or solid-state matter, such as gold for example, routes on quantum physics. It is the cooperative constructive interference of many electrons that forms the internal glue which keeps the matter together. We explore these and other quantum effects in model structures ranging from lithographically defined devices down to single molecules
The Link below include these theses, all in nano field though not always appear exclusive in theses titlesQuantum interference is the basis for the formation of most of our matter in daily life. The reason that atoms bind together to form molecules or solid-state matter, such as gold for example, routes on quantum physics. It is the cooperative constructive interference of many electrons that forms the internal glue which keeps the matter together. We explore these and other quantum effects in model structures ranging from lithographically defined devices down to single molecules
Quantum Dot Josephson Junctions in the Kondo Regime
Experiments on nonlocal processes in NS devices
Formation Mechanism and Resistance Fluctuations of Atomic Sized Junctions
Local Modification and Characterization of the Electronics Structure of Carbon Nanotubes
Nano Field Effect Transistor as Basic Building Blocks for Sensing
Exploring the Electrical Conductance of Single Molecules via Mechanically Controllable Break Junctions
Transport Measurements of Single Wall Carbon Nanotubes Multiterminal Devices with Normal and Ferromagnetic Contacts
Correlation and Interference Experiments with Edge States
Expanding the Horizon of Molecular Electronics via Nanoparticle Assemblies
Accessing the Quantum World Through Electronic Transport in Carbon Nanotubes
Growth of Single-Wall Carbon Nanotubes by Chemical VaporDeposition for Electrical Devices
An Experimental Invetsigation of Spin Polarized Transport in Carbon Nanotubes
Mechanical Controllable Break Junction in a Liquid Environment: A Tool to Measure Single Molecules
Liquid Effects on Single Contacted Carbon Nanotubes Grown by Chemical Vapor Deposition
Electrical Quantum shot noise in mesoscopic superconductor-semiconductor heterostructures
Electrical Characterization of Carbon Nanotubes grown by the Chemical Vapor Deposition Method
Electric Electron Transport in Multiwall Carbon Nanotubes
Electric Characterization of DNA
Fluctuation Phenomena in Low-Dimensional Conductors
Non-Equilibrium Coherent Transport in Meoscopic Conductors
Toward Single Molecule Electronics
Electronic Transport and Noise in Mesoscopic SNS/SFS-junctions
Electrical Properties of Single Multiwalled Carbon Nanotubes
Shot Noise in Nanoconductors
Experiments on nonlocal processes in NS devices
Formation Mechanism and Resistance Fluctuations of Atomic Sized Junctions
Local Modification and Characterization of the Electronics Structure of Carbon Nanotubes
Nano Field Effect Transistor as Basic Building Blocks for Sensing
Exploring the Electrical Conductance of Single Molecules via Mechanically Controllable Break Junctions
Transport Measurements of Single Wall Carbon Nanotubes Multiterminal Devices with Normal and Ferromagnetic Contacts
Correlation and Interference Experiments with Edge States
Expanding the Horizon of Molecular Electronics via Nanoparticle Assemblies
Accessing the Quantum World Through Electronic Transport in Carbon Nanotubes
Growth of Single-Wall Carbon Nanotubes by Chemical VaporDeposition for Electrical Devices
An Experimental Invetsigation of Spin Polarized Transport in Carbon Nanotubes
Mechanical Controllable Break Junction in a Liquid Environment: A Tool to Measure Single Molecules
Liquid Effects on Single Contacted Carbon Nanotubes Grown by Chemical Vapor Deposition
Electrical Quantum shot noise in mesoscopic superconductor-semiconductor heterostructures
Electrical Characterization of Carbon Nanotubes grown by the Chemical Vapor Deposition Method
Electric Electron Transport in Multiwall Carbon Nanotubes
Electric Characterization of DNA
Fluctuation Phenomena in Low-Dimensional Conductors
Non-Equilibrium Coherent Transport in Meoscopic Conductors
Toward Single Molecule Electronics
Electronic Transport and Noise in Mesoscopic SNS/SFS-junctions
Electrical Properties of Single Multiwalled Carbon Nanotubes
Shot Noise in Nanoconductors
Link
http://www.nanoelectronics.ch/publications/theses.php
Really Good Luck
