We analyze the interplay between vibrational and electronic degrees of freedom in charge transport across a molecular single-electron transistor. We focus on the wide class of molecules which possess quasidegenerate vibrational eigenstates, while no degeneracy occurs for their anionic configuration. We show that the combined effect of a thermal environment and coupling to leads, involving tunneling events charging and discharging the molecule, leads to a dynamical symmetry breaking where quasidegenerate eigenstates acquire different occupations. This imbalance gives rise to a characteristic asymmetry of the current versus an applied gate voltage
We study the tunneling conductance of nanoscale quantum “shuttles” in connection with a recent exper...
In this work, we develop a many-body theory of electronic transport through single molecule junction...
Transistors, regardless of their size, rely on electrical gates to control the conductance between s...
We analyze the interplay between vibrational and electronic degrees of freedom in charge transport a...
A theoretical model of a single molecule coupled to many vibronic modes is presented. At low energie...
This thesis is concerned with vibrational effects in resonant charge transport through molecular jun...
We study the model of a molecular switch comprised of a molecule with a soft vibrational degree of f...
Abstract. Transport through single molecules differs from transport through more conventional nanost...
The emerging eld of molecular electronics, in which individual molecules play the role of active de...
In the pursuit of down-sizing electronic components, the ultimate limit is the use of single molecul...
In single-molecule transistors, we observe inelastic cotunneling features that correspond energetica...
The general framework in which this thesis is embedded is called Molecular Electronics. In this fiel...
One of the central problems of molecular electronics is to understand electron conduction properties...
We present explicit kinetic equations for quantum transport through a general molecular quantum dot,...
In this Thesis we study several aspects of charge transport through single molecule junctions. Focu...
We study the tunneling conductance of nanoscale quantum “shuttles” in connection with a recent exper...
In this work, we develop a many-body theory of electronic transport through single molecule junction...
Transistors, regardless of their size, rely on electrical gates to control the conductance between s...
We analyze the interplay between vibrational and electronic degrees of freedom in charge transport a...
A theoretical model of a single molecule coupled to many vibronic modes is presented. At low energie...
This thesis is concerned with vibrational effects in resonant charge transport through molecular jun...
We study the model of a molecular switch comprised of a molecule with a soft vibrational degree of f...
Abstract. Transport through single molecules differs from transport through more conventional nanost...
The emerging eld of molecular electronics, in which individual molecules play the role of active de...
In the pursuit of down-sizing electronic components, the ultimate limit is the use of single molecul...
In single-molecule transistors, we observe inelastic cotunneling features that correspond energetica...
The general framework in which this thesis is embedded is called Molecular Electronics. In this fiel...
One of the central problems of molecular electronics is to understand electron conduction properties...
We present explicit kinetic equations for quantum transport through a general molecular quantum dot,...
In this Thesis we study several aspects of charge transport through single molecule junctions. Focu...
We study the tunneling conductance of nanoscale quantum “shuttles” in connection with a recent exper...
In this work, we develop a many-body theory of electronic transport through single molecule junction...
Transistors, regardless of their size, rely on electrical gates to control the conductance between s...