Cooling of electronic devices below 1 mK is a challenging task, since the thermal coupling with the dilution refrigerator becomes weak at low temperatures and electronic devices are extremely susceptible to external heat leaks such as microwave radiation and electrical noise. Despite these technological challenges, there is a completely new world of physics which can be explored once low temperatures are achieved. To reach such ultra-low temperatures, we implemented a parallel network of Nuclear Refrigerators, to adapt magnetic cooling to electronic transport measurements. The cooling scheme relies on the cooling of each individual lead by its own nuclear refrigerator to transfer cooling power down to the sample. Here, we present the i...
In labs across Europe physicists are pushing the boundaries of how far we can cool the electrons in ...
We present an improved nuclear refrigerator reaching 0.3 mK, aimed at microkelvin nanoelectronic exp...
We report the cooling of electrons in nanoelectronic Coulomb blockade thermometers below 4 mK. Above...
Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become ...
We demonstrate significant cooling of electrons in a nanostructure below 10mK by demagnetisation of ...
This thesis describes a novel cooling technique which allows the electrons within nanoelectronic dev...
On-chip demagnetization refrigeration has recently emerged as a powerful tool for reaching microkelv...
Nanostructured samples serve as a playground of solid state physics due to their vast diversity of a...
We present a new technique for on-chip cooling of electrons in a nanostructure: nuclear demagnetisat...
Here we review recent progress in cooling micro/nanoelectronic devices significantly below 10 mK. A ...
We present a parallel network of 16 demagnetization refrigerators mounted on a cryofree dilution ref...
Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become ...
Access to lower temperatures has consistently enabled scientific breakthroughs. Pushing the limits o...
Fragile quantum effects such as single electron charging in quantum dots or macroscopic coherent tun...
Cooling nanoelectronic structures to millikelvin temperatures presents extreme challenges in maintai...
In labs across Europe physicists are pushing the boundaries of how far we can cool the electrons in ...
We present an improved nuclear refrigerator reaching 0.3 mK, aimed at microkelvin nanoelectronic exp...
We report the cooling of electrons in nanoelectronic Coulomb blockade thermometers below 4 mK. Above...
Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become ...
We demonstrate significant cooling of electrons in a nanostructure below 10mK by demagnetisation of ...
This thesis describes a novel cooling technique which allows the electrons within nanoelectronic dev...
On-chip demagnetization refrigeration has recently emerged as a powerful tool for reaching microkelv...
Nanostructured samples serve as a playground of solid state physics due to their vast diversity of a...
We present a new technique for on-chip cooling of electrons in a nanostructure: nuclear demagnetisat...
Here we review recent progress in cooling micro/nanoelectronic devices significantly below 10 mK. A ...
We present a parallel network of 16 demagnetization refrigerators mounted on a cryofree dilution ref...
Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become ...
Access to lower temperatures has consistently enabled scientific breakthroughs. Pushing the limits o...
Fragile quantum effects such as single electron charging in quantum dots or macroscopic coherent tun...
Cooling nanoelectronic structures to millikelvin temperatures presents extreme challenges in maintai...
In labs across Europe physicists are pushing the boundaries of how far we can cool the electrons in ...
We present an improved nuclear refrigerator reaching 0.3 mK, aimed at microkelvin nanoelectronic exp...
We report the cooling of electrons in nanoelectronic Coulomb blockade thermometers below 4 mK. Above...