J1721+8842: A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Standard

J1721+8842 : A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber. / Lemon, C.; Millon, M.; Sluse, D.; Courbin, F.; Auger, M.; Chan, J. H.H.; Paic, E.; Agnello, A.

I: Astronomy and Astrophysics, Bind 657, A113, 01.01.2022.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Lemon, C, Millon, M, Sluse, D, Courbin, F, Auger, M, Chan, JHH, Paic, E & Agnello, A 2022, 'J1721+8842: A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber', Astronomy and Astrophysics, bind 657, A113. https://doi.org/10.1051/0004-6361/202142138

APA

Lemon, C., Millon, M., Sluse, D., Courbin, F., Auger, M., Chan, J. H. H., Paic, E., & Agnello, A. (2022). J1721+8842: A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber. Astronomy and Astrophysics, 657, [A113]. https://doi.org/10.1051/0004-6361/202142138

Vancouver

Lemon C, Millon M, Sluse D, Courbin F, Auger M, Chan JHH o.a. J1721+8842: A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber. Astronomy and Astrophysics. 2022 jan. 1;657. A113. https://doi.org/10.1051/0004-6361/202142138

Author

Lemon, C. ; Millon, M. ; Sluse, D. ; Courbin, F. ; Auger, M. ; Chan, J. H.H. ; Paic, E. ; Agnello, A. / J1721+8842 : A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber. I: Astronomy and Astrophysics. 2022 ; Bind 657.

Bibtex

@article{fc1666cc51d944629b9595e4b1732970,
title = "J1721+8842: A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber",
abstract = "High-redshift binary quasars provide key insights into mergers and quasar activity, and are useful tools for probing the spatial kinematics and chemistry of galaxies along the line of sight. However, only three sub-10-kpc binaries have been confirmed above z  =  1. Gravitational lensing would provide a way to easily resolve such binaries, study them in higher resolution, and provide more sightlines, though the required alignment with a massive foreground galaxy is rare. Through image deconvolution of StanCam Nordic Optical Telescope (NOT) monitoring data, we reveal two further point sources in the known, z  ≈  2.38, quadruply lensed quasar (quad) J1721+8842. An ALFOSC/NOT long-slit spectrum shows that the brighter of these two sources is a quasar with z  =  2.369  ±  0.007 based on the C » III] line, while the C » III] redshift of the quad is z  =  2.364  ±  0.003. Lens modelling using point-source positions rules out a single source model, favouring an isothermal lens mass profile with two quasar sources separated by ∼6.0 kpc (0.73″) in projection. Given the resolving ability from lensing and current lensed quasar statistics, this discovery suggests a large population of undiscovered, unlensed sub-10-kpc binaries. We also analyse spectra of two images of the quad, showing narrow Lyα emission within the trough of a proximate damped Lyman-α absorber (PDLA). An apparent mismatch between the continuum and narrow line flux ratios provides a new potential tool for simultaneously studying microlensing and the quasar host galaxy. Signs of the PDLA are also seen in the second source, but a deeper spectrum is still required to confirm this. Thanks to the multiple lines of sight from lensing and two quasar sources, this system offers simultaneous subparsec- and kiloparsec-scale probes of a PDLA. ",
keywords = "Gravitational lensing: strong, Quasars: general, Quasars: individual: J1721+8842",
author = "C. Lemon and M. Millon and D. Sluse and F. Courbin and M. Auger and Chan, {J. H.H.} and E. Paic and A. Agnello",
note = "Publisher Copyright: {\textcopyright} ESO 2022.",
year = "2022",
month = jan,
day = "1",
doi = "10.1051/0004-6361/202142138",
language = "English",
volume = "657",
journal = "Astronomy & Astrophysics",
issn = "0004-6361",
publisher = "E D P Sciences",

}

RIS

TY - JOUR

T1 - J1721+8842

T2 - A gravitationally lensed binary quasar with a proximate damped Lyman- α absorber

AU - Lemon, C.

AU - Millon, M.

AU - Sluse, D.

AU - Courbin, F.

AU - Auger, M.

AU - Chan, J. H.H.

AU - Paic, E.

AU - Agnello, A.

N1 - Publisher Copyright: © ESO 2022.

PY - 2022/1/1

Y1 - 2022/1/1

N2 - High-redshift binary quasars provide key insights into mergers and quasar activity, and are useful tools for probing the spatial kinematics and chemistry of galaxies along the line of sight. However, only three sub-10-kpc binaries have been confirmed above z  =  1. Gravitational lensing would provide a way to easily resolve such binaries, study them in higher resolution, and provide more sightlines, though the required alignment with a massive foreground galaxy is rare. Through image deconvolution of StanCam Nordic Optical Telescope (NOT) monitoring data, we reveal two further point sources in the known, z  ≈  2.38, quadruply lensed quasar (quad) J1721+8842. An ALFOSC/NOT long-slit spectrum shows that the brighter of these two sources is a quasar with z  =  2.369  ±  0.007 based on the C » III] line, while the C » III] redshift of the quad is z  =  2.364  ±  0.003. Lens modelling using point-source positions rules out a single source model, favouring an isothermal lens mass profile with two quasar sources separated by ∼6.0 kpc (0.73″) in projection. Given the resolving ability from lensing and current lensed quasar statistics, this discovery suggests a large population of undiscovered, unlensed sub-10-kpc binaries. We also analyse spectra of two images of the quad, showing narrow Lyα emission within the trough of a proximate damped Lyman-α absorber (PDLA). An apparent mismatch between the continuum and narrow line flux ratios provides a new potential tool for simultaneously studying microlensing and the quasar host galaxy. Signs of the PDLA are also seen in the second source, but a deeper spectrum is still required to confirm this. Thanks to the multiple lines of sight from lensing and two quasar sources, this system offers simultaneous subparsec- and kiloparsec-scale probes of a PDLA.

AB - High-redshift binary quasars provide key insights into mergers and quasar activity, and are useful tools for probing the spatial kinematics and chemistry of galaxies along the line of sight. However, only three sub-10-kpc binaries have been confirmed above z  =  1. Gravitational lensing would provide a way to easily resolve such binaries, study them in higher resolution, and provide more sightlines, though the required alignment with a massive foreground galaxy is rare. Through image deconvolution of StanCam Nordic Optical Telescope (NOT) monitoring data, we reveal two further point sources in the known, z  ≈  2.38, quadruply lensed quasar (quad) J1721+8842. An ALFOSC/NOT long-slit spectrum shows that the brighter of these two sources is a quasar with z  =  2.369  ±  0.007 based on the C » III] line, while the C » III] redshift of the quad is z  =  2.364  ±  0.003. Lens modelling using point-source positions rules out a single source model, favouring an isothermal lens mass profile with two quasar sources separated by ∼6.0 kpc (0.73″) in projection. Given the resolving ability from lensing and current lensed quasar statistics, this discovery suggests a large population of undiscovered, unlensed sub-10-kpc binaries. We also analyse spectra of two images of the quad, showing narrow Lyα emission within the trough of a proximate damped Lyman-α absorber (PDLA). An apparent mismatch between the continuum and narrow line flux ratios provides a new potential tool for simultaneously studying microlensing and the quasar host galaxy. Signs of the PDLA are also seen in the second source, but a deeper spectrum is still required to confirm this. Thanks to the multiple lines of sight from lensing and two quasar sources, this system offers simultaneous subparsec- and kiloparsec-scale probes of a PDLA.

KW - Gravitational lensing: strong

KW - Quasars: general

KW - Quasars: individual: J1721+8842

U2 - 10.1051/0004-6361/202142138

DO - 10.1051/0004-6361/202142138

M3 - Journal article

AN - SCOPUS:85123399016

VL - 657

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

SN - 0004-6361

M1 - A113

ER -

ID: 307337678