THE SPECTRAL VARIABILITY OF THE GHZ-PEAKED SPECTRUM RADIO SOURCE PKS 1718-649 AND A COMPARISON OF ABSORPTION MODELS

THE SPECTRAL VARIABILITY OF THE GHZ-PEAKED SPECTRUM RADIO SOURCE PKS 1718-649 AND A COMPARISON OF ABSORPTION MODELS

ABSTRACT Using the new wideband capabilities of the ATCA, we obtain spectra for PKS 1718-649, a well-known gigahertz-peaked spectrum radio source. The observations, between approximately 1 and 10 GHz over 3 epochs spanning approximately 21 months, reveal variability both above the spectral peak at ∼...

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Veröffentlicht in:The Astronomical journal 2015-02, Vol.149 (2), p.1-9
Hauptverfasser: Tingay, S. J., Macquart, J.-P., Collier, J. D., Rees, G., Callingham, J. R., Stevens, J., Carretti, E., Wayth, R. B., Wong, G. F., Trott, C. M., McKinley, B., Bernardi, G., Bowman, J. D., Briggs, F., Cappallo, R. J., Corey, B. E., Deshpande, A. A., Emrich, D., Gaensler, B. M., Goeke, R., Greenhill, L. J., Hazelton, B. J., Johnston-Hollitt, M., Kaplan, D. L., Kasper, J. C., Kratzenberg, E., Lonsdale, C. J., Lynch, M. J., McWhirter, S. R., Mitchell, D. A., Morales, M. F., Morgan, E., Oberoi, D., Ord, S. M., Prabu, T., Rogers, A. E. E., Roshi, A., Shankar, N. Udaya, Srivani, K. S., Subrahmanyan, R., Waterson, M., Webster, R. L., Whitney, A. R., Williams, A., Williams, C. L.
Format: Artikel
Sprache:eng
Schlagworte:
APPROXIMATIONS
Arrays
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
COMPARATIVE EVALUATIONS
DISTRIBUTION
EXPANSION
GALAXIES
galaxies: active
galaxies: individual (NGC 6328, PKS 1718-649)
GALAXY NUCLEI
GHZ RANGE
High frequencies
Line of sight
LINEAR ABSORPTION MODELS
radiation mechanisms: general
Radio
radio continuum: galaxies
SELF-ABSORPTION
SPECTRA
Spectral lines
SYNCHROTRONS
Wideband
X RADIATION
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container_end_page 9
container_issue 2
container_start_page 1
container_title The Astronomical journal
container_volume 149
creator Tingay, S. J.
Macquart, J.-P.
Collier, J. D.
Rees, G.
Callingham, J. R.
Stevens, J.
Carretti, E.
Wayth, R. B.
Wong, G. F.
Trott, C. M.
McKinley, B.
Bernardi, G.
Bowman, J. D.
Briggs, F.
Cappallo, R. J.
Corey, B. E.
Deshpande, A. A.
Emrich, D.
Gaensler, B. M.
Goeke, R.
Greenhill, L. J.
Hazelton, B. J.
Johnston-Hollitt, M.
Kaplan, D. L.
Kasper, J. C.
Kratzenberg, E.
Lonsdale, C. J.
Lynch, M. J.
McWhirter, S. R.
Mitchell, D. A.
Morales, M. F.
Morgan, E.
Oberoi, D.
Ord, S. M.
Prabu, T.
Rogers, A. E. E.
Roshi, A.
Shankar, N. Udaya
Srivani, K. S.
Subrahmanyan, R.
Waterson, M.
Webster, R. L.
Whitney, A. R.
Williams, A.
Williams, C. L.
description ABSTRACT Using the new wideband capabilities of the ATCA, we obtain spectra for PKS 1718-649, a well-known gigahertz-peaked spectrum radio source. The observations, between approximately 1 and 10 GHz over 3 epochs spanning approximately 21 months, reveal variability both above the spectral peak at ∼3 GHz and below the peak. The combination of the low- and high-frequency variability cannot be easily explained using a single absorption mechanism, such as free-free absorption or synchrotron self-absorption. We find that the PKS 1718-649 spectrum and its variability are best explained by variations in the free-free optical depth on our line of sight to the radio source at low frequencies (below the spectral peak) and the adiabatic expansion of the radio source itself at high frequencies (above the spectral peak). The optical depth variations are found to be plausible when X-ray continuum absorption variability seen in samples of active galactic nuclei is considered. We find that the cause of the peaked spectrum in PKS 1718-649 is most likely due to free-free absorption. In agreement with previous studies, we find that the spectrum at each epoch of observation is best fit by a free-free absorption model characterized by a power-law distribution of free-free absorbing clouds. This agreement is extended to frequencies below the 1 GHz lower limit of the ATCA by considering new observations with Parkes at 725 MHz and 199 MHz observations with the newly operational Murchison Widefield Array. These lower frequency observations argue against families of absorption models (both free-free and synchrotron self-absorption) that are based on simple homogenous structures.
doi_str_mv 10.1088/0004-6256/149/2/74
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J. ; Macquart, J.-P. ; Collier, J. D. ; Rees, G. ; Callingham, J. R. ; Stevens, J. ; Carretti, E. ; Wayth, R. B. ; Wong, G. F. ; Trott, C. M. ; McKinley, B. ; Bernardi, G. ; Bowman, J. D. ; Briggs, F. ; Cappallo, R. J. ; Corey, B. E. ; Deshpande, A. A. ; Emrich, D. ; Gaensler, B. M. ; Goeke, R. ; Greenhill, L. J. ; Hazelton, B. J. ; Johnston-Hollitt, M. ; Kaplan, D. L. ; Kasper, J. C. ; Kratzenberg, E. ; Lonsdale, C. J. ; Lynch, M. J. ; McWhirter, S. R. ; Mitchell, D. A. ; Morales, M. F. ; Morgan, E. ; Oberoi, D. ; Ord, S. M. ; Prabu, T. ; Rogers, A. E. E. ; Roshi, A. ; Shankar, N. Udaya ; Srivani, K. S. ; Subrahmanyan, R. ; Waterson, M. ; Webster, R. L. ; Whitney, A. R. ; Williams, A. ; Williams, C. L.</creator><creatorcontrib>Tingay, S. J. ; Macquart, J.-P. ; Collier, J. D. ; Rees, G. ; Callingham, J. R. ; Stevens, J. ; Carretti, E. ; Wayth, R. B. ; Wong, G. F. ; Trott, C. M. ; McKinley, B. ; Bernardi, G. ; Bowman, J. D. ; Briggs, F. ; Cappallo, R. J. ; Corey, B. E. ; Deshpande, A. A. ; Emrich, D. ; Gaensler, B. M. ; Goeke, R. ; Greenhill, L. J. ; Hazelton, B. J. ; Johnston-Hollitt, M. ; Kaplan, D. L. ; Kasper, J. C. ; Kratzenberg, E. ; Lonsdale, C. J. ; Lynch, M. J. ; McWhirter, S. R. ; Mitchell, D. A. ; Morales, M. F. ; Morgan, E. ; Oberoi, D. ; Ord, S. M. ; Prabu, T. ; Rogers, A. E. E. ; Roshi, A. ; Shankar, N. Udaya ; Srivani, K. S. ; Subrahmanyan, R. ; Waterson, M. ; Webster, R. L. ; Whitney, A. R. ; Williams, A. ; Williams, C. L.</creatorcontrib><description>ABSTRACT Using the new wideband capabilities of the ATCA, we obtain spectra for PKS 1718-649, a well-known gigahertz-peaked spectrum radio source. The observations, between approximately 1 and 10 GHz over 3 epochs spanning approximately 21 months, reveal variability both above the spectral peak at ∼3 GHz and below the peak. The combination of the low- and high-frequency variability cannot be easily explained using a single absorption mechanism, such as free-free absorption or synchrotron self-absorption. We find that the PKS 1718-649 spectrum and its variability are best explained by variations in the free-free optical depth on our line of sight to the radio source at low frequencies (below the spectral peak) and the adiabatic expansion of the radio source itself at high frequencies (above the spectral peak). The optical depth variations are found to be plausible when X-ray continuum absorption variability seen in samples of active galactic nuclei is considered. We find that the cause of the peaked spectrum in PKS 1718-649 is most likely due to free-free absorption. In agreement with previous studies, we find that the spectrum at each epoch of observation is best fit by a free-free absorption model characterized by a power-law distribution of free-free absorbing clouds. This agreement is extended to frequencies below the 1 GHz lower limit of the ATCA by considering new observations with Parkes at 725 MHz and 199 MHz observations with the newly operational Murchison Widefield Array. 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R.</creatorcontrib><creatorcontrib>Williams, A.</creatorcontrib><creatorcontrib>Williams, C. L.</creatorcontrib><title>THE SPECTRAL VARIABILITY OF THE GHZ-PEAKED SPECTRUM RADIO SOURCE PKS 1718-649 AND A COMPARISON OF ABSORPTION MODELS</title><title>The Astronomical journal</title><addtitle>AJ</addtitle><addtitle>Astron. J</addtitle><description>ABSTRACT Using the new wideband capabilities of the ATCA, we obtain spectra for PKS 1718-649, a well-known gigahertz-peaked spectrum radio source. The observations, between approximately 1 and 10 GHz over 3 epochs spanning approximately 21 months, reveal variability both above the spectral peak at ∼3 GHz and below the peak. The combination of the low- and high-frequency variability cannot be easily explained using a single absorption mechanism, such as free-free absorption or synchrotron self-absorption. We find that the PKS 1718-649 spectrum and its variability are best explained by variations in the free-free optical depth on our line of sight to the radio source at low frequencies (below the spectral peak) and the adiabatic expansion of the radio source itself at high frequencies (above the spectral peak). The optical depth variations are found to be plausible when X-ray continuum absorption variability seen in samples of active galactic nuclei is considered. We find that the cause of the peaked spectrum in PKS 1718-649 is most likely due to free-free absorption. In agreement with previous studies, we find that the spectrum at each epoch of observation is best fit by a free-free absorption model characterized by a power-law distribution of free-free absorbing clouds. This agreement is extended to frequencies below the 1 GHz lower limit of the ATCA by considering new observations with Parkes at 725 MHz and 199 MHz observations with the newly operational Murchison Widefield Array. These lower frequency observations argue against families of absorption models (both free-free and synchrotron self-absorption) that are based on simple homogenous structures.</description><subject>APPROXIMATIONS</subject><subject>Arrays</subject><subject>ASTROPHYSICS, COSMOLOGY AND ASTRONOMY</subject><subject>COMPARATIVE EVALUATIONS</subject><subject>DISTRIBUTION</subject><subject>EXPANSION</subject><subject>GALAXIES</subject><subject>galaxies: active</subject><subject>galaxies: individual (NGC 6328, PKS 1718-649)</subject><subject>GALAXY NUCLEI</subject><subject>GHZ RANGE</subject><subject>High frequencies</subject><subject>Line of sight</subject><subject>LINEAR ABSORPTION MODELS</subject><subject>radiation mechanisms: general</subject><subject>Radio</subject><subject>radio continuum: galaxies</subject><subject>SELF-ABSORPTION</subject><subject>SPECTRA</subject><subject>Spectral lines</subject><subject>SYNCHROTRONS</subject><subject>Wideband</subject><subject>X RADIATION</subject><issn>0004-6256</issn><issn>1538-3881</issn><issn>1538-3881</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2015</creationdate><recordtype>article</recordtype><recordid>eNqNkU9vmzAYh61qlZp1_QI7WeplFxr_w-CjS2iDSgoCMmm7WMYYjSgNKSaHffuBUvVUVbu81is_v9_hfQD4jtEdRmG4RAgxjxOfLzETS7IM2AVYYJ-GHg1D_AUs3oEr8NW5HUIYh4gtgKvWMSzzOKoKmcKfskjkfZIm1S-YPcD573H928tj-RSv3rDtBhZylWSwzLZFFMP8qYQ4wKHHmYDyeQUljLJNPjWV2fPcIu_LrMirZNo22SpOy2_gstV7Z2_e3muwfYiraO2l2WMSydQzzCejx9u6CbkwQjSWsJYgTWu_5qhtjWANrzkztW4oMYxbQjQWrY9pE7SWasq0RfQa3J57ezd2yplutOaP6Q8Ha0ZFCGUEIz5RP87UcehfT9aN6qVzxu73-mD7k1M4CBD1GQ7Ef6DUF9NAdELJGTVD79xgW3Ucuhc9_FUYqVmZmo2o2YialCmiAjaF7s6hrj-qXX8aDtN5Pg_cfhDQu3dCHZuW_gOW9Zey</recordid><startdate>20150201</startdate><enddate>20150201</enddate><creator>Tingay, S. 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J. ; Johnston-Hollitt, M. ; Kaplan, D. L. ; Kasper, J. C. ; Kratzenberg, E. ; Lonsdale, C. J. ; Lynch, M. J. ; McWhirter, S. R. ; Mitchell, D. A. ; Morales, M. F. ; Morgan, E. ; Oberoi, D. ; Ord, S. M. ; Prabu, T. ; Rogers, A. E. E. ; Roshi, A. ; Shankar, N. Udaya ; Srivani, K. S. ; Subrahmanyan, R. ; Waterson, M. ; Webster, R. L. ; Whitney, A. R. ; Williams, A. ; Williams, C. 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R.</creatorcontrib><creatorcontrib>Williams, A.</creatorcontrib><creatorcontrib>Williams, C. L.</creatorcontrib><collection>CrossRef</collection><collection>Meteorological &amp; Geoastrophysical Abstracts</collection><collection>Meteorological &amp; Geoastrophysical Abstracts - Academic</collection><collection>Technology Research Database</collection><collection>Aerospace Database</collection><collection>Advanced Technologies Database with Aerospace</collection><collection>OSTI.GOV</collection><jtitle>The Astronomical journal</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Tingay, S. J.</au><au>Macquart, J.-P.</au><au>Collier, J. D.</au><au>Rees, G.</au><au>Callingham, J. R.</au><au>Stevens, J.</au><au>Carretti, E.</au><au>Wayth, R. B.</au><au>Wong, G. F.</au><au>Trott, C. M.</au><au>McKinley, B.</au><au>Bernardi, G.</au><au>Bowman, J. D.</au><au>Briggs, F.</au><au>Cappallo, R. J.</au><au>Corey, B. E.</au><au>Deshpande, A. A.</au><au>Emrich, D.</au><au>Gaensler, B. M.</au><au>Goeke, R.</au><au>Greenhill, L. J.</au><au>Hazelton, B. J.</au><au>Johnston-Hollitt, M.</au><au>Kaplan, D. L.</au><au>Kasper, J. C.</au><au>Kratzenberg, E.</au><au>Lonsdale, C. J.</au><au>Lynch, M. J.</au><au>McWhirter, S. R.</au><au>Mitchell, D. A.</au><au>Morales, M. F.</au><au>Morgan, E.</au><au>Oberoi, D.</au><au>Ord, S. M.</au><au>Prabu, T.</au><au>Rogers, A. E. E.</au><au>Roshi, A.</au><au>Shankar, N. Udaya</au><au>Srivani, K. S.</au><au>Subrahmanyan, R.</au><au>Waterson, M.</au><au>Webster, R. L.</au><au>Whitney, A. R.</au><au>Williams, A.</au><au>Williams, C. L.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>THE SPECTRAL VARIABILITY OF THE GHZ-PEAKED SPECTRUM RADIO SOURCE PKS 1718-649 AND A COMPARISON OF ABSORPTION MODELS</atitle><jtitle>The Astronomical journal</jtitle><stitle>AJ</stitle><addtitle>Astron. J</addtitle><date>2015-02-01</date><risdate>2015</risdate><volume>149</volume><issue>2</issue><spage>1</spage><epage>9</epage><pages>1-9</pages><issn>0004-6256</issn><issn>1538-3881</issn><eissn>1538-3881</eissn><abstract>ABSTRACT Using the new wideband capabilities of the ATCA, we obtain spectra for PKS 1718-649, a well-known gigahertz-peaked spectrum radio source. The observations, between approximately 1 and 10 GHz over 3 epochs spanning approximately 21 months, reveal variability both above the spectral peak at ∼3 GHz and below the peak. The combination of the low- and high-frequency variability cannot be easily explained using a single absorption mechanism, such as free-free absorption or synchrotron self-absorption. We find that the PKS 1718-649 spectrum and its variability are best explained by variations in the free-free optical depth on our line of sight to the radio source at low frequencies (below the spectral peak) and the adiabatic expansion of the radio source itself at high frequencies (above the spectral peak). The optical depth variations are found to be plausible when X-ray continuum absorption variability seen in samples of active galactic nuclei is considered. We find that the cause of the peaked spectrum in PKS 1718-649 is most likely due to free-free absorption. In agreement with previous studies, we find that the spectrum at each epoch of observation is best fit by a free-free absorption model characterized by a power-law distribution of free-free absorbing clouds. This agreement is extended to frequencies below the 1 GHz lower limit of the ATCA by considering new observations with Parkes at 725 MHz and 199 MHz observations with the newly operational Murchison Widefield Array. These lower frequency observations argue against families of absorption models (both free-free and synchrotron self-absorption) that are based on simple homogenous structures.</abstract><cop>United States</cop><pub>The American Astronomical Society</pub><doi>10.1088/0004-6256/149/2/74</doi><tpages>9</tpages><orcidid>https://orcid.org/0000-0002-3973-8403</orcidid><orcidid>https://orcid.org/0000-0002-8475-2036</orcidid><orcidid>https://orcid.org/0000-0002-0916-7443</orcidid><orcidid>https://orcid.org/0000-0001-9080-0105</orcidid><oa>free_for_read</oa></addata></record>
fulltext fulltext_linktorsrc
identifier ISSN: 0004-6256
ispartof The Astronomical journal, 2015-02, Vol.149 (2), p.1-9
issn 0004-6256
1538-3881
1538-3881
language eng
recordid cdi_osti_scitechconnect_22342106
source IOP Publishing Free Content
subjects APPROXIMATIONS
Arrays
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
COMPARATIVE EVALUATIONS
DISTRIBUTION
EXPANSION
GALAXIES
galaxies: active
galaxies: individual (NGC 6328, PKS 1718-649)
GALAXY NUCLEI
GHZ RANGE
High frequencies
Line of sight
LINEAR ABSORPTION MODELS
radiation mechanisms: general
Radio
radio continuum: galaxies
SELF-ABSORPTION
SPECTRA
Spectral lines
SYNCHROTRONS
Wideband
X RADIATION
title THE SPECTRAL VARIABILITY OF THE GHZ-PEAKED SPECTRUM RADIO SOURCE PKS 1718-649 AND A COMPARISON OF ABSORPTION MODELS
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