Jamie Leech

The C-Band All-Sky Survey: total intensity point-source detection over the northern sky

Monthly Notices of the Royal Astronomical Society Oxford University Press 496:2 (2020) 1941-1958

Authors:

Rdp Grumitt, Angela Taylor, Luke Jew, Michael E Jones, C Dickinson, A Barr, R Cepeda-Arroita, Hc Chiang, Se Harper, Hm Heilgendorff, JL Jonas, JP Leahy, Jamie Leech, TJ Pearson, MW Peel, ACS Readhead, J Sievers

Abstract:

We present a point-source detection algorithm that employs the second-order Spherical Mexican Hat wavelet filter (SMHW2), and use it on C-Band All-Sky Survey (C-BASS) northern intensity data to produce a catalogue of point sources. This catalogue allows us to cross-check the C-BASS flux-density scale against existing source surveys, and provides the basis for a source mask that will be used in subsequent C-BASS and cosmic microwave background (CMB) analyses. The SMHW2 allows us to filter the entire sky at once, avoiding complications from edge effects arising when filtering small sky patches. The algorithm is validated against a set of Monte Carlo simulations, consisting of diffuse emission, instrumental noise, and various point-source populations. The simulated source populations are successfully recovered. The SMHW2 detection algorithm is used to produce a 4.76 GHz northern sky source catalogue in total intensity, containing 1784 sources and covering declinations δ ≥ −10°. The C-BASS catalogue is matched with the Green Bank 6 cm (GB6) and Parkes-MIT-NRAO (PMN) catalogues over their areas of common sky coverage. From this we estimate the 90 per cent completeness level to be approximately ⁠610 mJy, with a corresponding reliability of 98 per cent, when masking the brightest 30 per cent of the diffuse emission in the C-BASS northern sky map. We find the C-BASS and GB6 flux-density scales to be consistent with one another to within approximately 4 per cent.

A 1x4 focal plane array using 230 GHz SIS mixers

29th International Symposium on Space Terahertz Technology (ISSTT 2018) International Symposium on Space Terahertz Technology (2019) 240-244

Authors:

John Garrett, Jamie Leech, F Boussaha, C Chaumont, B Ellison, Ghassan Yassin

Abstract:

A new 1x4 focal plane array centered around 230 GHz is presented in this paper. The size of the array was limited to 4 pixels due to the space available in the test cryostat; however, we can expand the design in the future. On the front of the array block there are 4 waveguides flanges for the RF feed horns, while the local-oscillator signal enters through a separate waveguide on the side. The local-oscillator power is multiplexed using cascaded E-plane power dividers and then combined with the RF signals using directional couplers. Preliminary tests of the array block have now been completed. They show reasonable local-oscillator distribution and excellent RF signal isolation. Future work will involve testing the noise properties of the array block and improving the local-oscillator distribution.

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, Y Perrott, F Poidevin, ACS Readhead, J-A Rubiño-Martín, Angela C Taylor, CT Tibbs, M Todorovic, M Vidal

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 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

Automated reduction of sub-millimetre single-dish heterodyne data from the James Clerk Maxwell Telescope using orac-dr

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 453:1 (2015) 73-88

Authors:

Tim Jenness, Malcolm J Currie, Remo PJ Tilanus, Brad Cavanagh, David S Berry, Jamie Leech, Luca Rizzi