Add to ORKGImproved accessibility to the microkelvin temperature regime is important for future research in quantum materials; for quantum information science; and for applications of quantum sensors. Here we report the design and performance of a microkelvin platform based on a nuclear demagnetization stage, engineered and well optimized for operation on a standard cryogen-free dilution refrigerator. PrNi5 is used as the dominant refrigerant. The platform provides a large area for mounting experiments in an ultralow temperature, low electromagnetic noise environment. The performance is characterized using current sensing noise thermometry. Temperatures as low as 395 $\mu$K have been reached, and a protocol has been established in which it is possible...
AbstractResearchers attempting to study quantum effects in the solid-state have a need to characteri...
Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become ...
We demonstrate successful “dry” refrigeration of quantum fluids down to T = 0.16 mK by using copper ...
Access to lower temperatures has consistently enabled scientific breakthroughs. Pushing the limits o...
Temperatures below 1 mK on-chip hold great potential for quantum physics but present a great challen...
In labs across Europe physicists are pushing the boundaries of how far we can cool the electrons in ...
Fragile quantum effects such as single electron charging in quantum dots or macroscopic coherent tun...
Nanostructured samples serve as a playground of solid state physics due to their vast diversity of a...
We present a parallel network of 16 demagnetization refrigerators mounted on a cryofree dilution ref...
Of all parameters, determining the behaviour of a physical system in the laboratory, temperature is ...
Here we review recent progress in cooling micro/nanoelectronic devices significantly below 10 mK. A ...
The need for larger mK cooling platforms is being driven by the desire to host ever growing numbers ...
On-chip demagnetization refrigeration has recently emerged as a powerful tool for reaching microkelv...
Cooling of electronic devices below 1 mK is a challenging task, since the thermal coupling with the ...
Quantum computing promises an exponential speed-up of computation compared to what is nowadays achie...
AbstractResearchers attempting to study quantum effects in the solid-state have a need to characteri...
Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become ...
We demonstrate successful “dry” refrigeration of quantum fluids down to T = 0.16 mK by using copper ...
Access to lower temperatures has consistently enabled scientific breakthroughs. Pushing the limits o...
Temperatures below 1 mK on-chip hold great potential for quantum physics but present a great challen...
In labs across Europe physicists are pushing the boundaries of how far we can cool the electrons in ...
Fragile quantum effects such as single electron charging in quantum dots or macroscopic coherent tun...
Nanostructured samples serve as a playground of solid state physics due to their vast diversity of a...
We present a parallel network of 16 demagnetization refrigerators mounted on a cryofree dilution ref...
Of all parameters, determining the behaviour of a physical system in the laboratory, temperature is ...
Here we review recent progress in cooling micro/nanoelectronic devices significantly below 10 mK. A ...
The need for larger mK cooling platforms is being driven by the desire to host ever growing numbers ...
On-chip demagnetization refrigeration has recently emerged as a powerful tool for reaching microkelv...
Cooling of electronic devices below 1 mK is a challenging task, since the thermal coupling with the ...
Quantum computing promises an exponential speed-up of computation compared to what is nowadays achie...
AbstractResearchers attempting to study quantum effects in the solid-state have a need to characteri...
Cooling nanoelectronic devices below 10 mK is a great challenge since thermal conductivities become ...
We demonstrate successful “dry” refrigeration of quantum fluids down to T = 0.16 mK by using copper ...