http://arxiv.org/abs/2209.06088
High resolution polarization maps of the Cosmic Microwave Background (CMB) are on high demand, since the discovery of primordial B-Modes in the polarization patterns would confirm the inflationary phase of the Universe that would have taken place before the emission of the CMB. Transition Edge Sensors (TES) and Microwave Kinetic Inductance Detectors (MKID) are the predominant detector technologies of cryogenic detector array based CMB instruments that search for primordial B-Modes. In this paper we propose another type of cryogenic detector to be used for CMB survey: A magnetic microbolometer (MMB) that is based on a paramagnetic temperature sensor. It is an adaption of state-of-the-art metallic magnetic calorimeters (MMCs) that are meanwhile a key technology for high resolution $\alpha$, $\beta$, $\gamma$ and X-ray spectroscopy as well as the study of neutrino mass. A complete simulation framework was developed that accounts for the electrical and thermal properties of the bolometer and that can be used to obtain its responsivity and bandwidth, as well as estimating noise. A brief proof of concept case study is analyzed, taking into account typical constraints in CMB measurements and reliable microfabrication processes, to assess the suitability of metallic magnetic sensors in CMB experiments. The results show that MMBs provide a promising technology for CMB polarization measurements as their sensitivity can be tuned for background limited detection of the sky while simultaneously maintaining a low time response to avoid degradation of the point-source response of the telescope. As the sensor technology and its fabrication techniques are compatible with TES based bolometric detector arrays, a change of detector technology would even come with very low cost.
J. Geria, M. Hampel, S. Kempf, et. al.
Wed, 14 Sep 22
45/90
Comments: 18 pages, 14 figures. Paper submitted for review for the Journal of Astronomical Telescopes, Instruments and Systems (JATIS-SPIE)