The origin and the evolution of the universe are concealed in the evanescent diffuse extragalactic background radiation (DEBRA). To reveal these signals, the development of innovative ultra-sensitive bolometers operating in the gigahertz band is required. Here, we review the design and experimental realization of two bias-current-tunable sensors based on one dimensional fully superconducting Josephson junctions: the nanoscale transition edge sensor (nano-TES) and the Josephson escape sensor (JES). In particular, we cover the theoretical basis of the sensors operation, the device fabrication, their experimental electronic and thermal characterization and the deduced detection performance. Indeed, the nano-TES promises a state-of-the-art noise equivalent power (NEP) of about 5 × 10-20 W/?Hz, while the JES active region is expected to show an unprecedented NEP of the order of 10-25 W/?Hz. Therefore, the nano-TES and JES are strong candidates to push radio astronomy to the next level. © 2021 by the authors. Licensee MDPI, Basel, Switzerland.
Fully superconducting josephson bolometers for gigahertz astronomy
Paolucci F;Ligato N;Giazotto F
2021
Abstract
The origin and the evolution of the universe are concealed in the evanescent diffuse extragalactic background radiation (DEBRA). To reveal these signals, the development of innovative ultra-sensitive bolometers operating in the gigahertz band is required. Here, we review the design and experimental realization of two bias-current-tunable sensors based on one dimensional fully superconducting Josephson junctions: the nanoscale transition edge sensor (nano-TES) and the Josephson escape sensor (JES). In particular, we cover the theoretical basis of the sensors operation, the device fabrication, their experimental electronic and thermal characterization and the deduced detection performance. Indeed, the nano-TES promises a state-of-the-art noise equivalent power (NEP) of about 5 × 10-20 W/?Hz, while the JES active region is expected to show an unprecedented NEP of the order of 10-25 W/?Hz. Therefore, the nano-TES and JES are strong candidates to push radio astronomy to the next level. © 2021 by the authors. Licensee MDPI, Basel, Switzerland.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
