Bandwidth coverage of niobium based superconducting tunnel devices

The Atacama Large Millimeter/submillimeter Array (ALMA) is an astronomical observatory that is being built on a 5000 m altitude plateau in Chile to perform heterodyne measurements in the frequency range of 30 to 950 GHz. These measurements will reveal the presence of characteristic molecules that tell us more about the evolution of the early universe and the formation of stars and planetary systems. Because of the limited atmospherical transmission of radiation at these frequencies, ALMA is divided into 10 frequency bands with a sufficiently high transmission. This thesis describes the research that has been done to develop superconductor - insulator - superconductor (SIS) tunneljunctions as detectors for Band 9 of ALMA (602 - 720 GHz). To realize these devices, a tuning circuit has been developed that optimizes the coupling of electromagnetic radiation from the antenna to the SIS junction. Further, a new method has been developed to create SIS junctions with aluminum nitride (AlN) as the insulating material. This method uses a remote plasma from an inductively coupled plasma source. Junctions that have been grown with this new method show a much better uniformity in transmissivity of the tunneling barrier at high critical current densities. Using the new method, SIS devices with AlN tunnel barriers have been developed that have a record low noise temperature over the full bandwidth of Band 9.Applied Science

Shot-noise detection in a carbon nanotube quantum dot

Kavli Institute of Nanoscience DelftApplied Science

Bandwidth Limitations of Nb/AlN/Nb SIS Mixers Around 700 GHz

We study, using niobium-technology, the bandwidth of SIS mixers operating at frequencies close to the energy-gap frequency. Microstriplines of niobium-silicon dioxide-niobium have different properties for the top and bottom superconductor, which we find to depend on the used fabrication process. Replacing the AlOx tunnel barrier by AlN, the bandwidth increases by 53%. The measurements, using a Fourier Transform Spectrometer (FTS) and performed in ambient air, demonstrate that the bandwidth is no longer limited by the tuning circuit but by the atmospheric absorption of radiation. Excellent noise temperatures are found over a full band of 600 to 720 GHz.Kavli Institute of NanosciencesApplied Science