C-BASS

The state-of-play of Anomalous Microwave Emission (AME) research

New Astronomy Reviews Elsevier (2018)

Authors:

C Dickinson, Y Ali-Haïmoud, A Barr, ES Battistelli, A Bell, L Bernstein, S Cassassus, K Cleary, BT Draine, R Génova-Santos, Harper, B Hensley, Jaz R Hill-Valler, T Hoang, FP Israel, Luke Jew, A Lazarian, JP Leahy, Jamie Leech, CH López-Carabello, I McDonald, EJ Murphy, T Onaka, R Paladini, MW Peel

Abstract:

Anomalous Microwave Emission (AME) is a component of diffuse Galactic radiation observed at frequencies in the range ≈10–60 GHz. AME was first detected in 1996 and recognised as an additional component of emission in 1997. Since then, AME has been observed by a range of experiments and in a variety of environments. AME is spatially correlated with far-IR thermal dust emission but cannot be explained by synchrotron or free–free emission mechanisms, and is far in excess of the emission contributed by thermal dust emission with the powerlaw opacity consistent with the observed emission at sub-mm wavelengths. Polarization observations have shown that AME is very weakly polarized ( ≲ 1 %). The most natural explanation for AME is rotational emission from ultra-small dust grains (“spinning dust”), first postulated in 1957. Magnetic dipole radiation from thermal fluctuations in the magnetization of magnetic grain materials may also be contributing to the AME, particularly at higher frequencies ( ≳ 50 GHz). AME is also an important foreground for Cosmic Microwave Background analyses. This paper presents a review and the current state-of-play in AME research, which was discussed in an AME workshop held at ESTEC, The Netherlands, June 2016.

A compact quad-ridge orthogonal mode transducer with wide operational bandwidth

IEEE Antennas and Wireless Propagation Letters Institute of Electrical and Electronics Engineers 17:3 (2018) 422-425

Authors:

Alexander Pollak, Michael E Jones

Abstract:

We present the design and the measured performance of a compact quad-ridge orthomode transducer (OMT) operating in C-band with more than 100% fractional bandwidth. The OMT comprises two sets of identical orthogonal ridges mounted in a circular waveguide. The profile of these ridges was optimised to reduce significantly the transition length, while retaining the wide operational bandwidth of the quad-ridge OMT. In this letter, we show that the optimised compact OMT has better than -15dB return loss with the cross-polarisation well below -40dB in the designated 4.0-8.5GHz band.

The Low Frequency Receivers for SKA1-Low: Design and Verification

Institute of Electrical and Electronics Engineers (IEEE) (2017) 1-4

Authors:

Pieter Benthem, Marchel Gerbers, Jan Geralt Bij de Vaate, Stefan Wijnholds, Jeanette Bast, Tom Booler, Tim Colgate, Brian Crosse, David Emrich, Peter Hall, Budi Juswardy, David Kenney, Franz Schlazenhaufer, Marcin Sokolowski, Adrian Sutinjo, Daniel Ung, Randall Wayth, Andrew Williams, Monica Alderighi, Pietro Bolli, Gianni Comoretto, Andrea Mattana, Jader Monari, Giovanni Naldi, Frederico Perini, Giuseppe Pupillo, Simone Rusticelli, Marco Schiaffino, Francesco Schilliro, Amin Aminei, Riccardo Chiello, Mike Jones, Jeremy Baker, Richard Bennett, Rob Halsall, Georgina Kaligeridou, Matthew Roberts, Hermine Schnetler, Jens Abraham, Eloy De Lera Accdo, Andrew Faulkner, Nima Razavi Ghods, Denis Cutajar, Andrea DeMarco, Alessio Magro, Kristian Zarb Adami

A Herschel Space Observatory Spectral Line Survey of Local Luminous Infrared Galaxies from 194 to 671 Microns

ASTROPHYSICAL JOURNAL SUPPLEMENT SERIES 230:1 (2017) ARTN 1

Authors:

N Lu, Y Zhao, T Diaz-Santos, C Kevin Xu, Y Gao, L Armus, KG Isaak, JM Mazzarella, PP van der Werf, PN Appleton, V Charmandaris, AS Evans, J Howell, K Iwasawa, J Leech, S Lord, AO Petric, GC Privon, DB Sanders, B Schulz, JA Surace

HIPSR: A digital signal processor for the Parkes 21-cm multibeam receiver

Journal of Astronomical Instrumentation World Scientific Publishing 5:4 (2016)

Authors:

DC Price, L Staveley-Smith, M Bailes, E Carretti, A Jameson, Michael Jones, W van Straten, SW Schediwy

Abstract:

HIPSR (HI-Pulsar) is a digital signal processing system for the Parkes 21-cm Multibeam Receiver that provides larger instantaneous bandwidth, increased dynamic range, and more signal processing power than the previous systems in use at Parkes. The additional computational capacity enables finer spectral resolution in wideband HI observations and real-time detection of Fast Radio Bursts during pulsar surveys. HIPSR uses a heterogeneous architecture, consisting of FPGA-based signal processing boards connected via high-speed Ethernet to high performance compute nodes. Low-level signal processing is conducted on the FPGA-based boards, and more complex signal processing routines are conducted on the GPU-based compute nodes. The development of HIPSR was driven by two main science goals: to provide large bandwidth, high-resolution spectra suitable for 21-cm stacking and intensity mapping experiments; and to upgrade the Berkeley–Parkes–Swinburne Recorder (BPSR), the signal processing system used for the High Time Resolution Universe (HTRU) Survey and the Survey for Pulsars and Extragalactic Radio Bursts (SUPERB).