Transient obscuration event captured in NGC 3227: IV. Origin of the obscuring cloud variability

S. Grafton-Waters; J. Mao; M. Mehdipour; G. Branduardi-Raymont; M. Page; J. Kaastra; Y. Wang; C. Pinto; G. A. Kriss; D. J. Walton; P. O. Petrucci; G. Ponti; B. De Marco; S. Bianchi; E. Behar; J. Ebrero

doi:10.1051/0004-6361/202243681

Transient obscuration event captured in NGC 3227: IV. Origin of the obscuring cloud variability

S. Grafton-Waters, J. Mao, M. Mehdipour, G. Branduardi-Raymont, M. Page, J. Kaastra, Y. Wang, C. Pinto, G. A. Kriss, D. J. Walton, P. O. Petrucci, G. Ponti, B. De Marco, S. Bianchi, E. Behar, J. Ebrero

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Context. Obscuration events in type I active galactic nuclei (AGN) have been detected more frequently in recent years. The strong flux decrease in the soft X-ray band between observations has been caused by clouds with large column densities transiting our line of sight (LOS) and covering the central AGN. Another event has been captured in NGC 3227 at the end of 2019, which was observed with XMM-Newton, NuSTAR, and the Hubble Space Telescope. Aims. We aim to determine the nature and origin of the observed spectral variability in the 2019 obscuration event. Methods. We study the evolution of the obscurer by splitting the two XMM-Newton observations from 2019 into timing bins of length ~10 ks. We used the SPEX code to analyse the 0.35-10 keV EPIC-PN spectra of each timing bin. Results. In the first observation (Obs 1), there is a strong anti-correlation between the column density (NH) of the obscurer and the continuum normalisations of the X-ray power law and soft Comptonisation components (Npow and Ncomt, respectively). The power-law continuum models the hard X-rays produced by the corona, and the Comptonisation component models the soft X-ray excess and emission from the accretion disk. Through further testing, we conclude that the continuum is likely to drive the observed variability, but we cannot rule out a possible contribution from NH of the obscurer if it fully transverses across the ionising source within our LOS during the observation. The ionisation parameter (ξ) of the obscurer is not easily constrained, and therefore it is not clear whether it varies in response to changes in the ionising continuum. The second observation (Obs 2) displays a significantly lower count rate due to the combination of a high NH and covering fraction of the obscurer, and a lower continuum flux. Conclusions. The observed variability seen during the obscuration event of NGC 3227 in 2019 is likely driven by the continuum, but the obscurer varies at the same time, making it difficult to distinguish between the two possibilities with full certainty.

Original language	English
Article number	A26
Journal	Astronomy and Astrophysics
Volume	673
DOIs	https://doi.org/10.1051/0004-6361/202243681
State	Published - 27 Apr 2023

Keywords

Galaxies: Seyfert
Galaxies: active
Galaxies: individual: NGC 3227
Techniques: spectroscopic
X-rays: galaxies

All Science Journal Classification (ASJC) codes

Astronomy and Astrophysics
Space and Planetary Science

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10.1051/0004-6361/202243681

Cite this

Grafton-Waters, S., Mao, J., Mehdipour, M., Branduardi-Raymont, G., Page, M., Kaastra, J., Wang, Y., Pinto, C., Kriss, G. A., Walton, D. J., Petrucci, P. O., Ponti, G., De Marco, B., Bianchi, S., Behar, E., & Ebrero, J. (2023). Transient obscuration event captured in NGC 3227: IV. Origin of the obscuring cloud variability. Astronomy and Astrophysics, 673, Article A26. https://doi.org/10.1051/0004-6361/202243681

@article{8570a1d898324b6ca385bb10ffeaba3c,

title = "Transient obscuration event captured in NGC 3227: IV. Origin of the obscuring cloud variability",

abstract = "Context. Obscuration events in type I active galactic nuclei (AGN) have been detected more frequently in recent years. The strong flux decrease in the soft X-ray band between observations has been caused by clouds with large column densities transiting our line of sight (LOS) and covering the central AGN. Another event has been captured in NGC 3227 at the end of 2019, which was observed with XMM-Newton, NuSTAR, and the Hubble Space Telescope. Aims. We aim to determine the nature and origin of the observed spectral variability in the 2019 obscuration event. Methods. We study the evolution of the obscurer by splitting the two XMM-Newton observations from 2019 into timing bins of length ~10 ks. We used the SPEX code to analyse the 0.35-10 keV EPIC-PN spectra of each timing bin. Results. In the first observation (Obs 1), there is a strong anti-correlation between the column density (NH) of the obscurer and the continuum normalisations of the X-ray power law and soft Comptonisation components (Npow and Ncomt, respectively). The power-law continuum models the hard X-rays produced by the corona, and the Comptonisation component models the soft X-ray excess and emission from the accretion disk. Through further testing, we conclude that the continuum is likely to drive the observed variability, but we cannot rule out a possible contribution from NH of the obscurer if it fully transverses across the ionising source within our LOS during the observation. The ionisation parameter (ξ) of the obscurer is not easily constrained, and therefore it is not clear whether it varies in response to changes in the ionising continuum. The second observation (Obs 2) displays a significantly lower count rate due to the combination of a high NH and covering fraction of the obscurer, and a lower continuum flux. Conclusions. The observed variability seen during the obscuration event of NGC 3227 in 2019 is likely driven by the continuum, but the obscurer varies at the same time, making it difficult to distinguish between the two possibilities with full certainty.",

keywords = "Galaxies: Seyfert, Galaxies: active, Galaxies: individual: NGC 3227, Techniques: spectroscopic, X-rays: galaxies",

author = "S. Grafton-Waters and J. Mao and M. Mehdipour and G. Branduardi-Raymont and M. Page and J. Kaastra and Y. Wang and C. Pinto and Kriss, {G. A.} and Walton, {D. J.} and Petrucci, {P. O.} and G. Ponti and {De Marco}, B. and S. Bianchi and E. Behar and J. Ebrero",

year = "2023",

month = apr,

day = "27",

doi = "10.1051/0004-6361/202243681",

language = "الإنجليزيّة",

volume = "673",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

Grafton-Waters, S, Mao, J, Mehdipour, M, Branduardi-Raymont, G, Page, M, Kaastra, J, Wang, Y, Pinto, C, Kriss, GA, Walton, DJ, Petrucci, PO, Ponti, G, De Marco, B, Bianchi, S, Behar, E & Ebrero, J 2023, 'Transient obscuration event captured in NGC 3227: IV. Origin of the obscuring cloud variability', Astronomy and Astrophysics, vol. 673, A26. https://doi.org/10.1051/0004-6361/202243681

TY - JOUR

T1 - Transient obscuration event captured in NGC 3227

T2 - IV. Origin of the obscuring cloud variability

AU - Grafton-Waters, S.

AU - Mao, J.

AU - Mehdipour, M.

AU - Branduardi-Raymont, G.

AU - Page, M.

AU - Kaastra, J.

AU - Wang, Y.

AU - Pinto, C.

AU - Kriss, G. A.

AU - Walton, D. J.

AU - Petrucci, P. O.

AU - Ponti, G.

AU - De Marco, B.

AU - Bianchi, S.

AU - Behar, E.

AU - Ebrero, J.

PY - 2023/4/27

Y1 - 2023/4/27

N2 - Context. Obscuration events in type I active galactic nuclei (AGN) have been detected more frequently in recent years. The strong flux decrease in the soft X-ray band between observations has been caused by clouds with large column densities transiting our line of sight (LOS) and covering the central AGN. Another event has been captured in NGC 3227 at the end of 2019, which was observed with XMM-Newton, NuSTAR, and the Hubble Space Telescope. Aims. We aim to determine the nature and origin of the observed spectral variability in the 2019 obscuration event. Methods. We study the evolution of the obscurer by splitting the two XMM-Newton observations from 2019 into timing bins of length ~10 ks. We used the SPEX code to analyse the 0.35-10 keV EPIC-PN spectra of each timing bin. Results. In the first observation (Obs 1), there is a strong anti-correlation between the column density (NH) of the obscurer and the continuum normalisations of the X-ray power law and soft Comptonisation components (Npow and Ncomt, respectively). The power-law continuum models the hard X-rays produced by the corona, and the Comptonisation component models the soft X-ray excess and emission from the accretion disk. Through further testing, we conclude that the continuum is likely to drive the observed variability, but we cannot rule out a possible contribution from NH of the obscurer if it fully transverses across the ionising source within our LOS during the observation. The ionisation parameter (ξ) of the obscurer is not easily constrained, and therefore it is not clear whether it varies in response to changes in the ionising continuum. The second observation (Obs 2) displays a significantly lower count rate due to the combination of a high NH and covering fraction of the obscurer, and a lower continuum flux. Conclusions. The observed variability seen during the obscuration event of NGC 3227 in 2019 is likely driven by the continuum, but the obscurer varies at the same time, making it difficult to distinguish between the two possibilities with full certainty.

AB - Context. Obscuration events in type I active galactic nuclei (AGN) have been detected more frequently in recent years. The strong flux decrease in the soft X-ray band between observations has been caused by clouds with large column densities transiting our line of sight (LOS) and covering the central AGN. Another event has been captured in NGC 3227 at the end of 2019, which was observed with XMM-Newton, NuSTAR, and the Hubble Space Telescope. Aims. We aim to determine the nature and origin of the observed spectral variability in the 2019 obscuration event. Methods. We study the evolution of the obscurer by splitting the two XMM-Newton observations from 2019 into timing bins of length ~10 ks. We used the SPEX code to analyse the 0.35-10 keV EPIC-PN spectra of each timing bin. Results. In the first observation (Obs 1), there is a strong anti-correlation between the column density (NH) of the obscurer and the continuum normalisations of the X-ray power law and soft Comptonisation components (Npow and Ncomt, respectively). The power-law continuum models the hard X-rays produced by the corona, and the Comptonisation component models the soft X-ray excess and emission from the accretion disk. Through further testing, we conclude that the continuum is likely to drive the observed variability, but we cannot rule out a possible contribution from NH of the obscurer if it fully transverses across the ionising source within our LOS during the observation. The ionisation parameter (ξ) of the obscurer is not easily constrained, and therefore it is not clear whether it varies in response to changes in the ionising continuum. The second observation (Obs 2) displays a significantly lower count rate due to the combination of a high NH and covering fraction of the obscurer, and a lower continuum flux. Conclusions. The observed variability seen during the obscuration event of NGC 3227 in 2019 is likely driven by the continuum, but the obscurer varies at the same time, making it difficult to distinguish between the two possibilities with full certainty.

KW - Galaxies: Seyfert

KW - Galaxies: active

KW - Galaxies: individual: NGC 3227

KW - Techniques: spectroscopic

KW - X-rays: galaxies

UR - http://www.scopus.com/inward/record.url?scp=85156190205&partnerID=8YFLogxK

U2 - 10.1051/0004-6361/202243681

DO - 10.1051/0004-6361/202243681

M3 - مقالة

SN - 0004-6361

VL - 673

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A26

ER -

Transient obscuration event captured in NGC 3227: IV. Origin of the obscuring cloud variability

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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