Add to ORKGMesoscopic physics is the area of solid state physics that covers the transition regime between macroscopic objects and the microscopic atomic world. In this regime electron retains its phase coherence throughout the entire sample. At low temperatures mesoscopic systems exhibit a wonderful new range of unexpected quantum phenomena. In this article a brief sketch of this field is presented and we restrict ourselves to the basic physics involved
Electronic transport can roughly be divided into two regimes. For large bulk conductors the electron...
This thesis is concerned with the theoretical study of the transport in small conductors at low temp...
University of Minnesota Ph.D. dissertation. August 2009. Major: Physics. Advisor: Alex Kamenev. 1 co...
An ongoing tendency in modern material science is to propose and to investigate systems containing s...
Phase-coherent electron transport in metals and semiconductors forms the basis of the ¯eld called &q...
Future high-tech applications such as nanotechnology require a deep understanding of the physics of ...
The quantum phenomena of tunneling and interference show up not only in the microscopic world of ato...
In the framework of this work an overview of the theory of mesoscopic systems is made. The main effe...
Recent advances in semiconductor technology have made possible the fabrication of structures whose d...
Having driven a large part of the decade's progress in physics, nanoelectronics is now passing from ...
A thorough account of the theory of electronic transport in semiconductor nanostructures
Propagation in a random medium is often described by a random walk and a diffusion coefficient. Howe...
Models of nonequilibrium quantum transport underpin all modern electronic devices, from the largest ...
"Mesoscopic physics" refers to the physics of structures larger than a nanometer (one billionth of a...
In recent years submicron and nanoscale systems have featured strongly on the research agenda due to...
Electronic transport can roughly be divided into two regimes. For large bulk conductors the electron...
This thesis is concerned with the theoretical study of the transport in small conductors at low temp...
University of Minnesota Ph.D. dissertation. August 2009. Major: Physics. Advisor: Alex Kamenev. 1 co...
An ongoing tendency in modern material science is to propose and to investigate systems containing s...
Phase-coherent electron transport in metals and semiconductors forms the basis of the ¯eld called &q...
Future high-tech applications such as nanotechnology require a deep understanding of the physics of ...
The quantum phenomena of tunneling and interference show up not only in the microscopic world of ato...
In the framework of this work an overview of the theory of mesoscopic systems is made. The main effe...
Recent advances in semiconductor technology have made possible the fabrication of structures whose d...
Having driven a large part of the decade's progress in physics, nanoelectronics is now passing from ...
A thorough account of the theory of electronic transport in semiconductor nanostructures
Propagation in a random medium is often described by a random walk and a diffusion coefficient. Howe...
Models of nonequilibrium quantum transport underpin all modern electronic devices, from the largest ...
"Mesoscopic physics" refers to the physics of structures larger than a nanometer (one billionth of a...
In recent years submicron and nanoscale systems have featured strongly on the research agenda due to...
Electronic transport can roughly be divided into two regimes. For large bulk conductors the electron...
This thesis is concerned with the theoretical study of the transport in small conductors at low temp...
University of Minnesota Ph.D. dissertation. August 2009. Major: Physics. Advisor: Alex Kamenev. 1 co...