Refrigeration of separate, user-supplied payloads with Normal–Insulator–Superconductor tunnel junctions

Normal metal–Insulator–Superconductor (NIS) tunnel junctions can be used to selectively remove the hottest electrons in the normal metal, thereby causing it to cool. NIS tunnel junctions have already been used to cool lithographically integrated payloads [1], but this requires integration of two disparate fabrication processes. To increase the flexibility of NIS refrigerators, we have designed a stage cooler based on NIS tunnel junctions that will be able to cool arbitrary, user-supplied payloads from 300 mK to 100 mK. This stage cooler can be backed by a helium-3 refrigerator to provide a lightweight and simple means of reaching 100 mK in space applications. In this paper, we describe the design of our stage cooler and present calculations of the cooling power and time required to reach 100 mK.

► Design of an NIS cooler that can cool payloads from 300 mK to 100 mK is presented.
► The heat loads on the cold stage from the support structure are modeled.
► We expect 80 pW of cooling power at 100 mK.
► With updated devices, we expect 15 nW of cooling power at 100 mK.