The Square Kilometre Array (SKA)

Synergy between the large synoptic survey telescope and the square kilometre array

Proceedings of Science 9-13-June-2014 (2014)

Authors:

D Bacon, S Bridle, FB Abdalla, M Brown, P Bull, S Camera, R Fender, K Grainge, Ž Ivezíc, M Jarvis, N Jackson, D Kirk, B Mann, J McEwen, J McKean, J Newman, A Raccanelli, M Sahlén, M Santos, A Tyson, GB Zhao

Abstract:

We provide an overview of the science benefits of combining information from the Square Kilometre Array (SKA) and the Large Synoptic Survey Telescope (LSST). We first summarise the capabilities and timeline of the LSST and overview its science goals. We then discuss the science questions in common between the two projects, and how they can be best addressed by combining the data from both telescopes. We describe how weak gravitational lensing and galaxy clustering studies with LSST and SKA can provide improved constraints on the causes of the cosmological acceleration. We summarise the benefits to galaxy evolution studies of combining deep optical multi-band imaging with radio observations. Finally, we discuss the excellent match between one of the most unique features of the LSST, its temporal cadence in the optical waveband, and the time resolution of the SKA.

The SKA view of the interplay between SF and AGN Activity, and its role in Galaxy evolution

Proceedings of Science 9-13-June-2014 (2014)

Authors:

K Mcalpine, I Prandoni, M Jarvis, N Seymour, P Padovani, P Best, C Simpson, D Guidetti, E Murphy, M Huynh, M Vaccari, S White, R Beswick, J Afonso, M Magliocchetti, M Bondi

Abstract:

It has become apparent that active galactic nuclei (AGN) may have a significant impact on the growth and evolution of their host galaxies and vice versa but a detailed understanding of the interplay between these processes remains elusive. Deep radio surveys provide a powerful, obscuration-independent tool for measuring both star formation and AGN activity in highredshift galaxies. Multiwavelength studies of deep radio fields show a composite population of star-forming galaxies and AGN, with the former dominating at the lowest flux densities (S1:4GHz <100 mJy). The sensitivity and resolution of the SKA will allow us to identify, and separately trace, the total star formation in the bulges of individual high-redshift galaxies, the related nuclear activity and any star formation occurring on larger scales within a disc. We will therefore gain a detailed picture of the apparently simultaneous development of stellar populations and black holes in the redshift range where both star-formation and AGN activity peak (1z4). In this chapter we discuss the role of the SKA in studying the connection between AGN activity and galaxy evolution, and the most critical technical requirements for such of studies.

The astrophysics of star formation across cosmic time at &10 GHz with the square kilometre array

Proceedings of Science 9-13-June-2014 (2014)

Authors:

EJ Murphy, MT Sargent, RJ Beswick, C Dickinson, I Heywood, LK Hunt, MT Hyunh, M Jarvis, A Karim, M Krause, I Prandoni, N Seymour, E Schinnerer, FS Tabatabaei, J Wagg

Abstract:

In this chapter, we highlight a number of science investigations that are enabled by the inclusion of Band 5 (4:613:8 GHz) for SKA1-MID science operations, while focusing on the astrophysics of star formation over cosmic time. For studying the detailed astrophysics of star formation at highredshift, surveys at frequencies &10 GHz have the distinct advantage over traditional ∼1.4 GHz surveys as they are able to yield higher angular resolution imaging while probing higher rest frame frequencies of galaxies with increasing redshift, where emission of star-forming galaxies becomes dominated by thermal (free-free) radiation. In doing so, surveys carried out at &10 GHz provide a robust, dust-unbiased measurement of the massive star formation rate by being highly sensitive to the number of ionizing photons that are produced. To access this powerful star formation rate diagnostic requires that Band 5 be available for SKA1-MID. We additionally present a detailed science case for frequency coverage extending up to 30 GHz during full SKA2 operations, as this allows for highly diverse science while additionally providing contiguous frequency coverage between the SKA and ALMA, which will likely be the two most powerful interferometers for the coming decades. To enable this synergy, it is crucial that the dish design of the SKA be flexible enough to include the possibility of being fit with receivers operating up to 30 GHz.

The cosmic dawn and epoch of reionization with the square kilometre array

Proceedings of Science 9-13-June-2014 (2014)

Authors:

LVE Koopmans, J Pritchard, G Mellema, F Abdalla, J Aguirre, K Ahn, R Barkana, I Van Bemmel, G Bernardi, A Bonaldi, F Briggs, AG De Bruyn, TC Chang, E Chapman, X Chen, B Ciardi, KK Datta, P Dayal, A Ferrara, A Fialkov, F Fiore, K Ichiki, IT Illiev, S Inoue, V Jelić, M Jones, J Lazio, U Maio, S Majumdar, KJ Mack, A Mesinger, MF Morales, A Parsons, UL Pen, M Santos, R Schneider, B Semelin, RS De Souza, R Subrahmanyan, T Takeuchi, C Trott, H Vedantham, J Wagg, R Webster, S Wyithe

Abstract:

Concerted effort is currently ongoing to open up the Epoch of Reionization (z ∼15-6) for studies with IR and radio telescopes. Whereas IR detections have been made of sources (Lyman-a emitters, quasars and drop-outs) in this redshift regime in relatively small fields of view, no direct detection of neutral hydrogen, via the redshifted 21-cm line, has yet been established. Such a direct detection is expected in the coming years, with ongoing surveys, and could open up the entire universe from z ∼6-200 for astrophysical and cosmological studies, opening not only the Epoch of Reionization, but also its preceding Cosmic Dawn (z ∼30-15) and possibly even the later phases of the Dark Ages (z ∼200-30). All currently ongoing experiments attempt statistical detections of the 21-cm signal during the Epoch of Reionization, with limited signal-to-noise. Direct imaging, except maybe on the largest (degree) scales at lower redshifts, as well as higher redshifts will remain out of reach. The Square Kilometre Array (SKA) will revolutionize the field, allowing direct imaging of neutral hydrogen from scales of arc-minutes to degrees over most of the redshift range z ∼6-28 with SKA1-LOW, and possibly even higher redshifts with the SKA2-LOW. In this SKA will be unique, and in parallel provide enormous potential of synergy with other upcoming facilities (e.g. JWST). In this chapter we summarize the physics of 21-cm emission, the different phases the universe is thought to go through, and the observables that the SKA can probe, referring where needed to detailed chapters in this volume. This is done within the framework of the current SKA1 baseline design and a nominal CD/EoR straw-man survey, consisting of a shallow, medium-deep and deep survey, the latter probing down to ∼1mK brightness temperature on arc-minute scales at the end of reionization. Possible minor modifications to the design of SKA1 and the upgrade to SKA2 are discussed, in addition to science that could be done already during roll-out when SKA1 still has limited capabilities and/or core collecting area.

The cosmic evolution of Fermi BL Lacertae objects

Astrophysical Journal 780:1 (2014)

Authors:

M Ajello, RW Romani, D Gasparrini, MS Shaw, J Bolmer, G Cotter, J Finke, J Greiner, SE Healey, O King, W Max-Moerbeck, PF Michelson, WJ Potter, A Rau, ACS Readhead, JL Richards, P Schady

Abstract:

Fermi has provided the largest sample of γ-ray-selected blazars to date. In this work we use a uniformly selected set of 211 BL Lacertae (BL Lac) objects detected by Fermi during its first year of operation. We obtained redshift constraints for 206 out of the 211 BL Lac objects in our sample, making it the largest and most complete sample of BL Lac objects available in the literature. We use this sample to determine the luminosity function of BL Lac objects and its evolution with cosmic time. We find that for most BL Lac classes the evolution is positive, with a space density peaking at modest redshift (z ≈ 1.2). Low-luminosity, high-synchrotron-peaked (HSP) BL Lac objects are an exception, showing strong negative evolution, with number density increasing for z ≲ 0.5. Since this rise corresponds to a drop-off in the density of flat-spectrum radio quasars (FSRQs), a possible interpretation is that these HSPs represent an accretion-starved end state of an earlier merger-driven gas-rich phase. We additionally find that the known BL Lac correlation between luminosity and photon spectral index persists after correction for the substantial observational selection effects with implications for the so-called "blazar sequence." Finally, by estimating the beaming corrections to the luminosity function, we find that BL Lac objects have an average Lorentz factor of , and that most are seen within 10° of the jet axis. © 2014. The American Astronomical Society. All rights reserved.