The far-infrared/radio correlation as probed by Herschel

R. J. Ivison (UK ATC; IfA; Edinburgh); B. Magnelli; E. Ibar; P.; Andreani; D. Elbaz; B. Altieri; A. Amblard; V. Arumugam; R. Auld; H. Aussel,; T. Babbedge; S. Berta; A. Blain; J. Bock; A. Bongiovanni; A. Boselli; V.; Buat; D. Burgarella; N. Castro; A. Cava; J. Cepa; P. Chanial; A. Cimatti; M.; Cirasuolo; D. L. Clements; A. Conley; L. Conversi; A. Cooray; E. Daddi; H.; Dominguez; C. D. Dowell; E. Dwek; S. Eales; D. Farrah,; M. Fox; A.; Franceschini; W. Gear; R. Genzel; J. Glenn; M. Griffin; C. Gruppioni; M.; Halpern; E. Hatziminaoglou; K. Isaak; G. Lagache; L. Levenson; N. Lu; D.; Lutz; S. Madden; B. Maffei; G. Magdis; G. Mainetti; R. Maiolino; L.; Marchetti; G. E. Morrison; A. M. J. Mortier; H. T. Nguyen; R. Nordon; B.; O'Halloran; S. J. Oliver; A. Omont; F. N. Owen; M. J. Page; P. Panuzzo; A.; Papageorgiou; C. P. Pearson,; A.; A. Poglitsch; M. Pohlen; P. Popesso; F.; Pozzi; J. I. Rawlings; G. Raymond; D. Rigopoulou; L. Riguccini; D. Rizzo; G.; Rodighiero; I. G. Roseboom; M. Rowan-Robinson; A. Saintonge; M. Sanchez; Portal; P. Santini; B. Schulz; Douglas Scott; N. Seymour; L. Shao; D. L.; Shupe; A. J. Smith; J. A. Stevens; E. Sturm; M. Symeonidis; L. Tacconi; M.; Trichas; K. E. Tugwell; M. Vaccari; I. Valtchanov; J. Vieira; L. Vigroux; L.; Wang; R. Ward; G. Wright; C. K. Xu; M. Zemcov

arXiv:1005.1072·astro-ph.CO·May 18, 2015

The far-infrared/radio correlation as probed by Herschel

R. J. Ivison (UK ATC, IfA, Edinburgh), B. Magnelli, E. Ibar, P., Andreani, D. Elbaz, B. Altieri, A. Amblard, V. Arumugam, R. Auld, H. Aussel,, T. Babbedge, S. Berta, A. Blain, J. Bock, A. Bongiovanni, A. Boselli, V., Buat, D. Burgarella, N. Castro, A. Cava, J. Cepa, P. Chanial

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TL;DR

This study investigates the far-infrared/radio correlation in galaxies across different redshifts, luminosities, and dust temperatures using Herschel and VLA data, finding minimal evolution over cosmic time.

Contribution

It provides the first comprehensive analysis of q(IR) evolution with redshift, luminosity, and dust temperature using multi-wavelength data and stacking techniques.

Findings

01

Tentative break in q(IR) at L(1.4GHz) ~ 10^22.7 W/Hz indicating AGN influence.

02

Weak correlation of q(IR) with redshift and dust temperature.

03

Modest evolution of q(IR) with redshift, possibly related to the radio background.

Abstract

We set out to determine the ratio, q(IR), of rest-frame 8-1000um flux, S(IR), to monochromatic radio flux, S(1.4GHz), for galaxies selected at far-IR and radio wavelengths, to search for signs that the ratio evolves with redshift, luminosity or dust temperature, and to identify any far-IR-bright outliers - useful laboratories for exploring why the far-IR/radio correlation is generally so tight when the prevailing theory suggests variations are almost inevitable. We use flux-limited 250-um and 1.4-GHz samples, obtained in GOODS-N using Herschel (HerMES; PEP) and the VLA. We determine bolometric IR output using ten bands spanning 24-1250um, exploiting data from PACS and SPIRE, as well as Spitzer, SCUBA, AzTEC and MAMBO. We also explore the properties of an L(IR)-matched sample, designed to reveal evolution of q(IR) with z, spanning log L(IR) = 11-12 L(sun) and z=0-2, by stacking into the…

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