Rubin-LSST

The first Hubble diagram and cosmological constraints using superluminous supernovae

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 504:2 (2021) 2535-2549

Authors:

C Inserra, M Sullivan, CR Angus, E Macaulay, RC Nichol, M Smith, C Frohmaier, CP Gutiérrez, M Vicenzi, A Möller, D Brout, PJ Brown, TM Davis, CB D’Andrea, L Galbany, R Kessler, AG Kim, Y-C Pan, M Pursiainen, D Scolnic, BP Thomas, P Wiseman, TMC Abbott, J Annis, S Avila, E Bertin, D Brooks, DL Burke, A Carnero Rosell, M Carrasco Kind, J Carretero, FJ Castander, R Cawthon, S Desai, HT Diehl, TF Eifler, DA Finley, B Flaugher, P Fosalba, J Frieman, J Garcia-Bellido, E Gaztanaga, DW Gerdes, T Giannantonio, D Gruen, RA Gruendl, J Gschwend, G Gutierrez, DL Hollowood, K Honscheid, DJ James, E Krause, K Kuehn, N Kuropatkin, TS Li, C Lidman, M Lima, MAG Maia, JL Marshall, P Martini, F Menanteau, R Miquel, AA Plazas Malagón, AK Romer, A Roodman, M Sako, E Sanchez, V Scarpine, M Schubnell, S Serrano, I Sevilla-Noarbe, M Soares-Santos, F Sobreira, E Suchyta, MEC Swanson, G Tarle, D Thomas, DL Tucker, V Vikram, AR Walker, Y Zhang, J Asorey, J Calcino, D Carollo, K Glazebrook, SR Hinton, JK Hoormann, GF Lewis, R Sharp, E Swann, BE Tucker

A space mission to map the entire observable universe using the CMB as a backlight: Voyage 2050 science white paper

Experimental Astronomy (2021)

Authors:

K Basu, M Remazeilles, JB Melin, D Alonso, JG Bartlett, N Battaglia, J Chluba, E Churazov, J Delabrouille, J Erler, S Ferraro, C Hernández-Monteagudo, JC Hill, SC Hotinli, I Khabibullin, M Madhavacheril, T Mroczkowski, D Nagai, S Raghunathan, JAR Martin, J Sayers, D Scott, N Sugiyama, R Sunyaev, Í Zubeldia

Abstract:

This Science White Paper, prepared in response to the ESA Voyage 2050 call for long-term mission planning, aims to describe the various science possibilities that can be realized with an L-class space observatory that is dedicated to the study of the interactions of cosmic microwave background (CMB) photons with the cosmic web. Our aim is specifically to use the CMB as a backlight – and survey the gas, total mass, and stellar content of the entire observable Universe by means of analyzing the spatial and spectral distortions imprinted on it. These distortions result from two major processes that impact on CMB photons: scattering by free electrons and atoms (Sunyaev-Zeldovich effect in diverse forms, Rayleigh scattering, resonant scattering) and deflection by gravitational potential (lensing effect). Even though the list of topics collected in this White Paper is not exhaustive, it helps to illustrate the exceptional diversity of major scientific questions that can be addressed by a space mission that will reach an angular resolution of 1.5 arcmin (goal 1 arcmin), have an average sensitivity better than 1 μK-arcmin, and span the microwave frequency range from roughly 50 GHz to 1 THz. The current paper also highlights the synergy of our Backlight mission concept with several upcoming and proposed ground-based CMB experiments.

Strong low-frequency radio flaring from Cygnus X-3 observed with LOFAR

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 504:1 (2021) 1482-1494

Authors:

JW Broderick, TD Russell, RP Fender, SA Trushkin, DA Green, J Chauhan, NA Nizhelskij, PG Tsybulev, NN Bursov, AV Shevchenko, GG Pooley, DRA Williams, JS Bright, A Rowlinson, S Corbel

HI intensity mapping with the MIGHTEE survey: power spectrum estimates

Monthly Notices of the Royal Astronomical Society Oxford University Press 505:2 (2021) 2039-2050

Authors:

Sourabh Paul, Mario G Santos, Junaid Townsend, Matt J Jarvis, Natasha Maddox, Jordan D Collier, Bradley S Frank, Russ Taylor

Abstract:

Intensity mapping (IM) with neutral hydrogen is a promising avenue to probe the large-scale structure of the Universe. In this paper, we demonstrate that using the 64-dish MeerKAT radio telescope as a connected interferometer, it is possible to make a statistical detection of H I in the post-reionization Universe. With the MIGHTEE (MeerKAT International GHz Tiered Extragalactic Exploration) survey project observing in the L-band (856 MHz < ν < 1712 MHz, z < 0.66), we can achieve the required sensitivity to measure the H I IM power spectrum on quasi-linear scales, which will provide an important complementarity to the single-dish IM MeerKAT observations. We present a purpose-built simulation pipeline that emulates the MIGHTEE observations and forecasts the constraints that can be achieved on the H I power spectrum at z = 0.27 for k > 0.3 Mpc−1 using the foreground avoidance method. We present the power spectrum estimates with the current simulation on the COSMOS field that includes contributions from H I, noise, and point-source models constructed from the observed MIGHTEE data. The results from our visibility-based pipeline are in qualitative agreement to the already available MIGHTEE data. This paper demonstrates that MeerKAT can achieve very high sensitivity to detect H I with the full MIGHTEE survey on quasi-linear scales (signal-to-noise ratio >7 at k = 0.49 Mpc−1⁠) that are instrumental in probing cosmological quantities such as the spectral index of fluctuation, constraints on warm dark matter, the quasi-linear redshift space distortions, and the measurement of the H I content of the Universe up to z ∼ 0.5.

Low-frequency radio spectra of submillimetre galaxies in the Lockman Hole

Astronomy and Astrophysics European Southern Observatory 648 (2021) A14

Authors:

J Ramasawmy, Je Geach, Mj Hardcastle, Pn Best, M Bonato, M Bondi, G Calistro Rivera, Rk Cochrane, Je Conway, K Coppin, Kj Duncan, Js Dunlop, M Franco, C Garcia-Vergara, Matt Jarvis, R Kondapally, I McCheyne, I Prandoni, Hja Rottgering, Djb Smith, C Tasse, L Wang

Abstract:

Aims. We investigate the radio properties of a sample of 850 μm-selected sources from the SCUBA-2 Cosmology Legacy Survey (S2CLS) using new deep, low-frequency radio imaging of the Lockman Hole field from the Low Frequency Array. This sample consists of 53 sources, 41 of which are detected at >5σ at 150 MHz.
Methods. Combining these data with additional observations at 324 MHz, 610 MHz, and 1.4 GHz from the Giant Metrewave Radio Telescope and the Jansky Very Large Array, we find a variety of radio spectral shapes and luminosities (L1.4 GHz ranging from ~4 × 1023−1 × 1025) within our sample despite their similarly bright submillimetre flux densities (>4 mJy). We characterise their spectral shapes in terms of multi-band radio spectral indices. Finding strong spectral flattening at low frequencies in ~20% of sources, we investigate the differences between sources with extremely flat low-frequency spectra and those with ‘normal’ radio spectral indices (α > −0.25).
Results. As there are no other statistically significant differences between the two subgroups of our sample as split by the radio spectral index, we suggest that any differences are undetectable in galaxy-averaged properties that we can observe with our unresolved images, and likely relate to galaxy properties that we cannot resolve, on scales ≲1 kpc. We attribute the observed spectral flattening in the radio to free–free absorption, proposing that those sources with significant low-frequency spectral flattening have a clumpy distribution of star-forming gas. We estimate an average spatial extent of absorbing material of at most several hundred parsecs to produce the levels of absorption observed in the radio spectra. This estimate is consistent with the highest-resolution observations of submillimetre galaxies in the literature, which find examples of non-uniform dust distributions on scales of ~100 pc, with evidence for clumps and knots in the interstellar medium. Additionally, we find two bright (>6 mJy) S2CLS sources undetected at all other wavelengths. We speculate that these objects may be very high redshift sources, likely residing at z > 4.