Corrigendum: A large light-mass component of cosmic rays at 1017-1017.5 electronvolts from radio observations.

Nature Nature Publishing Group 537:7621 (2016) 572

Authors:

S Buitink, A Corstanje, H Falcke, T Huege, A Nelles, JP Rachen, L Rossetto, P Schellart, O Scholten, S Ter Veen, S Thoudam, TNG Trinh, J Anderson, A Asgekar, IM Avruch, ME Bell, MJ Bentum, G Bernardi, P Best, A Bonafede, F Breitling, JW Broderick, WN Brouw, M Brüggen, HR Butcher, D Carbone, B Ciardi, JE Conway, F de Gasperin, E de Geus, A Deller, R-J Dettmar, G van Diepen, S Duscha, J Eislöffel, D Engels, JE Enriquez, RA Fallows, Robert P Fender, C Ferrari, W Frieswijk, MA Garrett, JM Grießmeier, AW Gunst, van van Haarlem, TE Hassall, G Heald, JWT Hessels, M Hoeft

Abstract:

In this Letter, we omitted to cite preliminary results from the low-energy extension of the Pierre Auger Observatory, as presented at the International Cosmic Ray Conference 2015 (ref. 1). Figure 1 of this Corrigendum shows measurements of the average value of Xmax for the Low Frequency Array (LOFAR), and earlier experiments using different techniques, now including the data from the Pierre Auger Observatory1 , specifically the contribution of A. Porcelli. Our values are in agreement with those of ref. 1 within systematic uncertainties.

Low-radio-frequency eclipses of the redback pulsar J2215+5135 observed in the image plane with LOFAR

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 459:3 (2016) 2681-2689

Authors:

JW Broderick, RP Fender, RP Breton, AJ Stewart, A Rowlinson, JD Swinbank, JWT Hessels, TD Staley, AJ van der Horst, ME Bell, D Carbone, Y Cendes, S Corbel, J Eislöffel, H Falcke, J-M Grießmeier, TE Hassall, P Jonker, M Kramer, M Kuniyoshi, CJ Law, S Markoff, GJ Molenaar, M Pietka, LHA Scheers, M Serylak, BW Stappers, S Ter Veen, J van Leeuwen, RAMJ Wijers, R Wijnands, MW Wise, P Zarka

New methods to constrain the radio transient rate: results from a survey of four fields with LOFAR

Monthly Notices of the Royal Astronomical Society Oxford University Press (OUP) 459:3 (2016) 3161-3174

Authors:

D Carbone, AJ van der Horst, RAMJ Wijers, JD Swinbank, A Rowlinson, JW Broderick, YN Cendes, AJ Stewart, ME Bell, RP Breton, S Corbel, J Eislöffel, RP Fender, J-M Grießmeier, JWT Hessels, P Jonker, M Kramer, CJ Law, JCA Miller-Jones, M Pietka, LHA Scheers, BW Stappers, J van Leeuwen, R Wijnands, M Wise, P Zarka

Evidence for simultaneous jets and disk winds in luminous low-mass X-ray binaries

(2016)

Authors:

Jeroen Homan, Joseph Neilsen, Jessamyn L Allen, Deepto Chakrabarty, Rob Fender, Joel K Fridriksson, Ronald A Remillard, Norbert Schulz

HELP: star formation as function of galaxy environment with Herschel

Monthly Notices of the Royal Astronomical Society Oxford University Press (2016)

Authors:

S Duivenvoorden, S Oliver, V Buat, B Darvish, A Efstathiou, D Farrah, M Griffin, PD Hurley, E Ibar, Matthew Jarvis, A Papadopoulos, MT Sargent, D Scott, JM Scudder, M Symeonidis, M Vaccari, MP Viero, L Wang

Abstract:

The Herschel Extragalactic Legacy Project (HELP) brings together a vast range of data from many astronomical observatories. Its main focus is on the Herschel data, which maps dust obscured star formation over 1300 deg$^2$. With this unprecedented combination of data sets, it is possible to investigate how the star formation vs stellar mass relation (main-sequence) of star-forming galaxies depends on environment. In this pilot study we explore this question between 0.1 < z < 3.2 using data in the COSMOS field. We estimate the local environment from a smoothed galaxy density field using the full photometric redshift probability distribution. We estimate star formation rates by stacking the SPIRE data from the Herschel Multi-tiered Extragalactic Survey (HerMES). Our analysis rules out the hypothesis that the main-sequence for star-forming systems is independent of environment at 1.5 < z < 2, while a simple model in which the mean specific star formation rate declines with increasing environmental density gives a better description. However, we cannot exclude a simple hypothesis in which the main-sequence for star-forming systems is independent of environment at z < 1.5 and z > 2. We also estimate the evolution of the star formation rate density in the COSMOS field and our results are consistent with previous measurements at z < 1.5 and z > 2 but we find a $1.4^{+0.3}_{-0.2}$ times higher peak value of the star formation rate density at $z \sim 1.9$.