Molecules as tracers of galaxy evolution: an EMIR survey I. Presentation of the data and first results

F. Costagliola; S. Aalto; M. I. Rodriguez; S. Muller; H. W. W. Spoon; S. Martin; M. A. Perez-Torres; A. Alberdi; J. E. Lindberg; F. Batejat; E. Juette; F. Lahuis; Paul P. van der Werf

doi:10.1051/0004-6361/201015628

Molecules as tracers of galaxy evolution: an EMIR survey I. Presentation of the data and first results

F. Costagliola^*, S. Aalto, M. I. Rodriguez, S. Muller, H. W. W. Spoon, S. Martin, M. A. Perez-Torres, A. Alberdi, J. E. Lindberg, F. Batejat, E. Juette, F. Lahuis, Paul P. van der Werf

^*Corresponding author for this work

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Abstract

Aims. We investigate the molecular gas properties of a sample of 23 galaxies in order to find and test chemical signatures of galaxy evolution and to compare them to IR evolutionary tracers.

Methods. Observation at 3 mm wavelengths were obtained with the EMIR broadband receiver, mounted on the IRAM 30 m telescope on Pico Veleta, Spain. We compare the emission of the main molecular species with existing models of chemical evolution by means of line intensity ratios diagrams and principal component analysis.

Results. We detect molecular emission in 19 galaxies in two 8 GHz-wide bands centred at 88 and 112 GHz. The main detected molecules are CO, (CO)-C-13, HCN, HNC, HCO+, CN, and C2H. We also detect HC3N J = 10-9 in the galaxies IRAS 17208, IC 860, NGC 4418, NGC 7771, and NGC 1068. The only HC3N detections are in objects with HCO+/HCN <1. Galaxies with the highest HC3N/HCN ratios have warm IRAS colours (60/100 mu m > 0.8). The brightest HC3N emission is found in IC 860, where we also detect the molecule in its vibrationally excited state. We find low HNC/HCN line ratios (

Conclusions. Bright HC3N emission in HCO+-faint objects may imply that these are not dominated by X-ray chemistry. Thus the HCN/HCO+ line ratio is not, by itself, a reliable tracer of XDRs. Bright HC3N and faint HCO+ could be signatures of embedded star-formation, instead of AGN activity. Mechanical heating caused by supernova explosions may be responsible for the low HNC/HCN and high HCO+/HCN ratios in some starbursts. We cannot exclude, however, that the discussed trends are largely caused by optical depth effects or excitation. Chemical models alone cannot explain all properties of the observed molecular emission. Better constraints to the gas spacial distribution and excitation are needed to distinguish abundance and excitation effects.

Original language	English
Article number	30
Number of pages	28
Journal	Astronomy & Astrophysics
Volume	528
DOIs	https://doi.org/10.1051/0004-6361/201015628
Publication status	Published - Apr-2011

Keywords

evolution
ISM: molecules
galaxies: evolution
galaxies: ISM
galaxies: active
LUMINOUS INFRARED GALAXIES
VIBRATIONALLY EXCITED HC3N
MASSIVE STAR-FORMATION
HNC LINE EMISSION
DENSE GAS
INTERSTELLAR-MEDIUM
SEYFERT-GALAXIES
NEARBY GALAXIES
ARP 220
ABUNDANCES

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Costagliola, F., Aalto, S., Rodriguez, M. I., Muller, S., Spoon, H. W. W., Martin, S., Perez-Torres, M. A., Alberdi, A., Lindberg, J. E., Batejat, F., Juette, E., Lahuis, F., & van der Werf, P. P. (2011). Molecules as tracers of galaxy evolution: an EMIR survey I. Presentation of the data and first results. Astronomy & Astrophysics, 528, Article 30. https://doi.org/10.1051/0004-6361/201015628

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title = "Molecules as tracers of galaxy evolution: an EMIR survey I. Presentation of the data and first results",

abstract = "Aims. We investigate the molecular gas properties of a sample of 23 galaxies in order to find and test chemical signatures of galaxy evolution and to compare them to IR evolutionary tracers.Methods. Observation at 3 mm wavelengths were obtained with the EMIR broadband receiver, mounted on the IRAM 30 m telescope on Pico Veleta, Spain. We compare the emission of the main molecular species with existing models of chemical evolution by means of line intensity ratios diagrams and principal component analysis.Results. We detect molecular emission in 19 galaxies in two 8 GHz-wide bands centred at 88 and 112 GHz. The main detected molecules are CO, (CO)-C-13, HCN, HNC, HCO+, CN, and C2H. We also detect HC3N J = 10-9 in the galaxies IRAS 17208, IC 860, NGC 4418, NGC 7771, and NGC 1068. The only HC3N detections are in objects with HCO+/HCN <1. Galaxies with the highest HC3N/HCN ratios have warm IRAS colours (60/100 mu m > 0.8). The brightest HC3N emission is found in IC 860, where we also detect the molecule in its vibrationally excited state. We find low HNC/HCN line ratios (Conclusions. Bright HC3N emission in HCO+-faint objects may imply that these are not dominated by X-ray chemistry. Thus the HCN/HCO+ line ratio is not, by itself, a reliable tracer of XDRs. Bright HC3N and faint HCO+ could be signatures of embedded star-formation, instead of AGN activity. Mechanical heating caused by supernova explosions may be responsible for the low HNC/HCN and high HCO+/HCN ratios in some starbursts. We cannot exclude, however, that the discussed trends are largely caused by optical depth effects or excitation. Chemical models alone cannot explain all properties of the observed molecular emission. Better constraints to the gas spacial distribution and excitation are needed to distinguish abundance and excitation effects.",

keywords = "evolution, ISM: molecules, galaxies: evolution, galaxies: ISM, galaxies: active, LUMINOUS INFRARED GALAXIES, VIBRATIONALLY EXCITED HC3N, MASSIVE STAR-FORMATION, HNC LINE EMISSION, DENSE GAS, INTERSTELLAR-MEDIUM, SEYFERT-GALAXIES, NEARBY GALAXIES, ARP 220, ABUNDANCES",

author = "F. Costagliola and S. Aalto and Rodriguez, {M. I.} and S. Muller and Spoon, {H. W. W.} and S. Martin and Perez-Torres, {M. A.} and A. Alberdi and Lindberg, {J. E.} and F. Batejat and E. Juette and F. Lahuis and {van der Werf}, {Paul P.}",

year = "2011",

month = apr,

doi = "10.1051/0004-6361/201015628",

language = "English",

volume = "528",

journal = "Astronomy & Astrophysics",

issn = "0004-6361",

publisher = " EDP Sciences",

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TY - JOUR

T1 - Molecules as tracers of galaxy evolution

T2 - an EMIR survey I. Presentation of the data and first results

AU - Costagliola, F.

AU - Aalto, S.

AU - Rodriguez, M. I.

AU - Muller, S.

AU - Spoon, H. W. W.

AU - Martin, S.

AU - Perez-Torres, M. A.

AU - Alberdi, A.

AU - Lindberg, J. E.

AU - Batejat, F.

AU - Juette, E.

AU - Lahuis, F.

AU - van der Werf, Paul P.

PY - 2011/4

Y1 - 2011/4

N2 - Aims. We investigate the molecular gas properties of a sample of 23 galaxies in order to find and test chemical signatures of galaxy evolution and to compare them to IR evolutionary tracers.Methods. Observation at 3 mm wavelengths were obtained with the EMIR broadband receiver, mounted on the IRAM 30 m telescope on Pico Veleta, Spain. We compare the emission of the main molecular species with existing models of chemical evolution by means of line intensity ratios diagrams and principal component analysis.Results. We detect molecular emission in 19 galaxies in two 8 GHz-wide bands centred at 88 and 112 GHz. The main detected molecules are CO, (CO)-C-13, HCN, HNC, HCO+, CN, and C2H. We also detect HC3N J = 10-9 in the galaxies IRAS 17208, IC 860, NGC 4418, NGC 7771, and NGC 1068. The only HC3N detections are in objects with HCO+/HCN <1. Galaxies with the highest HC3N/HCN ratios have warm IRAS colours (60/100 mu m > 0.8). The brightest HC3N emission is found in IC 860, where we also detect the molecule in its vibrationally excited state. We find low HNC/HCN line ratios (Conclusions. Bright HC3N emission in HCO+-faint objects may imply that these are not dominated by X-ray chemistry. Thus the HCN/HCO+ line ratio is not, by itself, a reliable tracer of XDRs. Bright HC3N and faint HCO+ could be signatures of embedded star-formation, instead of AGN activity. Mechanical heating caused by supernova explosions may be responsible for the low HNC/HCN and high HCO+/HCN ratios in some starbursts. We cannot exclude, however, that the discussed trends are largely caused by optical depth effects or excitation. Chemical models alone cannot explain all properties of the observed molecular emission. Better constraints to the gas spacial distribution and excitation are needed to distinguish abundance and excitation effects.

AB - Aims. We investigate the molecular gas properties of a sample of 23 galaxies in order to find and test chemical signatures of galaxy evolution and to compare them to IR evolutionary tracers.Methods. Observation at 3 mm wavelengths were obtained with the EMIR broadband receiver, mounted on the IRAM 30 m telescope on Pico Veleta, Spain. We compare the emission of the main molecular species with existing models of chemical evolution by means of line intensity ratios diagrams and principal component analysis.Results. We detect molecular emission in 19 galaxies in two 8 GHz-wide bands centred at 88 and 112 GHz. The main detected molecules are CO, (CO)-C-13, HCN, HNC, HCO+, CN, and C2H. We also detect HC3N J = 10-9 in the galaxies IRAS 17208, IC 860, NGC 4418, NGC 7771, and NGC 1068. The only HC3N detections are in objects with HCO+/HCN <1. Galaxies with the highest HC3N/HCN ratios have warm IRAS colours (60/100 mu m > 0.8). The brightest HC3N emission is found in IC 860, where we also detect the molecule in its vibrationally excited state. We find low HNC/HCN line ratios (Conclusions. Bright HC3N emission in HCO+-faint objects may imply that these are not dominated by X-ray chemistry. Thus the HCN/HCO+ line ratio is not, by itself, a reliable tracer of XDRs. Bright HC3N and faint HCO+ could be signatures of embedded star-formation, instead of AGN activity. Mechanical heating caused by supernova explosions may be responsible for the low HNC/HCN and high HCO+/HCN ratios in some starbursts. We cannot exclude, however, that the discussed trends are largely caused by optical depth effects or excitation. Chemical models alone cannot explain all properties of the observed molecular emission. Better constraints to the gas spacial distribution and excitation are needed to distinguish abundance and excitation effects.

KW - evolution

KW - ISM: molecules

KW - galaxies: evolution

KW - galaxies: ISM

KW - galaxies: active

KW - LUMINOUS INFRARED GALAXIES

KW - VIBRATIONALLY EXCITED HC3N

KW - MASSIVE STAR-FORMATION

KW - HNC LINE EMISSION

KW - DENSE GAS

KW - INTERSTELLAR-MEDIUM

KW - SEYFERT-GALAXIES

KW - NEARBY GALAXIES

KW - ARP 220

KW - ABUNDANCES

U2 - 10.1051/0004-6361/201015628

DO - 10.1051/0004-6361/201015628

M3 - Article

SN - 0004-6361

VL - 528

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

M1 - 30

ER -

Molecules as tracers of galaxy evolution: an EMIR survey I. Presentation of the data and first results

Abstract

Keywords

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