Partenaires

Logo ens
CNRS
Logo P6
Logo P7

 


Search

On this website


Laboratoire Pierre Aigrain

Home page > Research at L.P.A. > Quantum circuits and conductors > Mesoscopic physics > Hybrid Quantum Circuits

Hybrid Quantum Circuits

Carbon nanotubes are molecular conductors which can be used to explore various aspects of quantum transport. The study of electrical transport leads to couple them to different kinds of metals which have very different properties in general. Single wall carbon nanotubes are naturally one dimensional conductors with four conducting channels (including spin) whereas the electrodes are generally 3D metals. These metals can display various electronic orders (superconducting or ferromagnetic) and are in the weak interaction regime. This is not the case for single wall nanotubes in which strong departures from the physics of non-interacting electrons have been found in the last decade. It is worth mentioning Coulomb blockade, the Kondo effect or the Luttinger liquid physics. A single wall carbon nanotube is therefore the archetype of a hybrid structure where different kinds of electronic orders and/or dimensionalities can be combined. The potential of single wall nanotubes for implementing various kinds of hybrid structures corresponding to “thought experiments” of quantum transport is illustrated for example by some of the devices which we have studied recently within the HQC team. The first structure is the Cooper pair splitter. The second one is a multiterminal nano spin-vavle. The third one is an artificial Kondo impurity. The study of these three devices relies on the nanofabrication of samples with single wall nanotubes connected to ferromagnets and/or superconductors possibly with high transparency for the contacts. We use for that purpose nanolithography techniques, chemical vapor deposition (CVD) growth and thin film deposition techniques under UHV.

Team Members

Team leader : Dr. Takis Kontos
PhD students : M.R. Delbecq, J.J. Viennot et A.D. Crisan
Postdoc : Dr. S. Datta

Read more