Add to ORKGA double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. The spectrum of two-electron eigenstates is investigated using electric dipole spin resonance. Singlet-triplet level repulsion caused by spin-orbit interaction is observed. The size and the anisotropy of singlet-triplet repulsion are used to determine the magnitude and the orientation of the spin-orbit effective field in an InSb nanowire double dot. The obtained results are confirmed using spin blockade leakage current anisotropy and transport spectroscopy of individual quantum dots
The motion of an electron and its spin are generally not coupled. However in a one-dimensional mater...
The motion of an electron and its spin are generally not coupled. However in a one-dimensional mater...
We have achieved the few-electron regime in InAs nanowire double quantum dots. Spin blockade is obse...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
Because of the strong spin-orbit interaction in indium antimonide, orbital motion and spin are no lo...
Motion of electrons can influence their spins through a fundamental effect called spin–orbit interac...
Because of the strong spin-orbit interaction in indium antimonide, orbital motion and spin are no lo...
The motion of an electron and its spin are generally not coupled. However in a one-dimensional mater...
The motion of an electron and its spin are generally not coupled. However in a one-dimensional mater...
We have achieved the few-electron regime in InAs nanowire double quantum dots. Spin blockade is obse...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
A double quantum dot in the few-electron regime is achieved using local gating in an InSb nanowire. ...
Because of the strong spin-orbit interaction in indium antimonide, orbital motion and spin are no lo...
Motion of electrons can influence their spins through a fundamental effect called spin–orbit interac...
Because of the strong spin-orbit interaction in indium antimonide, orbital motion and spin are no lo...
The motion of an electron and its spin are generally not coupled. However in a one-dimensional mater...
The motion of an electron and its spin are generally not coupled. However in a one-dimensional mater...
We have achieved the few-electron regime in InAs nanowire double quantum dots. Spin blockade is obse...