Quenching of Star Formation in Molecular Outflow Host NGC 1266

K. Alatalo; K. E. Nyland; G. Graves; S. Deustua; L. M. Young; T. A. Davis; A. F. Crocker; M. Bureau; E. Bayet; L. Blitz; M. Bois; F. Bournaud; M. Cappellari; R. L. Davies; P. T. de Zeeuw; E. Emsellem; S. Khochfar; D. Krajnovic; H. Kuntschner; R. M. McDermid; R. Morganti; T. Naab; T. Oosterloo; M. Sarzi; N. Scott; P. Serra; A. Weijmans; Tony Wong; Jürgen Ott

doi:10.1017/S1743921313001725

Quenching of Star Formation in Molecular Outflow Host NGC 1266

K. Alatalo, K. E. Nyland, G. Graves, S. Deustua, L. M. Young, T. A. Davis, A. F. Crocker, M. Bureau, E. Bayet, L. Blitz, M. Bois, F. Bournaud, M. Cappellari, R. L. Davies, P. T. de Zeeuw, E. Emsellem, S. Khochfar, D. Krajnovic, H. Kuntschner, R. M. McDermidR. Morganti, T. Naab, T. Oosterloo, M. Sarzi, N. Scott, P. Serra, A. Weijmans, Tony Wong, Jürgen Ott

Astronomy

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic

Abstract

We detail the rich molecular story of NGC 1266, its serendipitous discovery within the ATLAS3D survey (Cappellari et al. 2011) and how it plays host to an AGN-driven molecular outflow, potentially quenching all of its star formation (SF) within the next 100 Myr. While major mergers appear to play a role in instigating outflows in other systems, deep imaging of NGC 1266 as well as stellar kinematic observations from SAURON, have failed to provide evidence that NGC 1266 has recently been involved in a major interaction. The molecular gas and the instantaneous SF tracers indicate that the current sites of star formation are located in a hypercompact disk within 200 pc of the nucleus (Fig. 1; SF rate ≈ 2 M ⊙ yr-1). On the other hand, tracers of recent star formation, such as the Hβ absorption map from SAURON and stellar population analysis show that the young stars are distributed throughout a larger area of the galaxy than current star formation. As the AGN at the center of NGC 1266 continues to drive cold gas out of the galaxy, we expect star formation rates to decline as the star formation is ultimately quenched. Thus, NGC 1266 is in the midst of a key portion of its evolution and continued studies of this unique galaxy may help improve our understanding of how galaxies transition from the blue to the red sequence (Alatalo et al. 2011).

Original language	English
Title of host publication	IAU Symposium 292. Molecular Gas, Dust and Star Formation in Galaxies Proceedings IAU Symposium No. 292, 2012
Pages	371-371
Number of pages	1
DOIs	https://doi.org/10.1017/S1743921313001725
Publication status	Published - Mar-2013

Keywords

galaxies: evolution
galaxies: individual (NGC 1266)
galaxies: active

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Alatalo, K., Nyland, K. E., Graves, G., Deustua, S., Young, L. M., Davis, T. A., Crocker, A. F., Bureau, M., Bayet, E., Blitz, L., Bois, M., Bournaud, F., Cappellari, M., Davies, R. L., de Zeeuw, P. T., Emsellem, E., Khochfar, S., Krajnovic, D., Kuntschner, H., ... Ott, J. (2013). Quenching of Star Formation in Molecular Outflow Host NGC 1266. In IAU Symposium 292. Molecular Gas, Dust and Star Formation in Galaxies Proceedings IAU Symposium No. 292, 2012 (pp. 371-371) https://doi.org/10.1017/S1743921313001725

@inproceedings{fe0d94dca6fa419786dda268e8b2e9f3,

title = "Quenching of Star Formation in Molecular Outflow Host NGC 1266",

abstract = "We detail the rich molecular story of NGC 1266, its serendipitous discovery within the ATLAS3D survey (Cappellari et al. 2011) and how it plays host to an AGN-driven molecular outflow, potentially quenching all of its star formation (SF) within the next 100 Myr. While major mergers appear to play a role in instigating outflows in other systems, deep imaging of NGC 1266 as well as stellar kinematic observations from SAURON, have failed to provide evidence that NGC 1266 has recently been involved in a major interaction. The molecular gas and the instantaneous SF tracers indicate that the current sites of star formation are located in a hypercompact disk within 200 pc of the nucleus (Fig. 1; SF rate ≈ 2 M ⊙ yr-1). On the other hand, tracers of recent star formation, such as the Hβ absorption map from SAURON and stellar population analysis show that the young stars are distributed throughout a larger area of the galaxy than current star formation. As the AGN at the center of NGC 1266 continues to drive cold gas out of the galaxy, we expect star formation rates to decline as the star formation is ultimately quenched. Thus, NGC 1266 is in the midst of a key portion of its evolution and continued studies of this unique galaxy may help improve our understanding of how galaxies transition from the blue to the red sequence (Alatalo et al. 2011).",

keywords = "galaxies: evolution, galaxies: individual (NGC 1266), galaxies: active",

author = "K. Alatalo and Nyland, {K. E.} and G. Graves and S. Deustua and Young, {L. M.} and Davis, {T. A.} and Crocker, {A. F.} and M. Bureau and E. Bayet and L. Blitz and M. Bois and F. Bournaud and M. Cappellari and Davies, {R. L.} and {de Zeeuw}, {P. T.} and E. Emsellem and S. Khochfar and D. Krajnovic and H. Kuntschner and McDermid, {R. M.} and R. Morganti and T. Naab and T. Oosterloo and M. Sarzi and N. Scott and P. Serra and A. Weijmans and Tony Wong and J{\"u}rgen Ott",

note = "M1 - Conference Proceedings",

year = "2013",

month = mar,

doi = "10.1017/S1743921313001725",

language = "English",

pages = "371--371",

booktitle = "IAU Symposium 292. Molecular Gas, Dust and Star Formation in Galaxies Proceedings IAU Symposium No. 292, 2012",

}

Alatalo, K, Nyland, KE, Graves, G, Deustua, S, Young, LM, Davis, TA, Crocker, AF, Bureau, M, Bayet, E, Blitz, L, Bois, M, Bournaud, F, Cappellari, M, Davies, RL, de Zeeuw, PT, Emsellem, E, Khochfar, S, Krajnovic, D, Kuntschner, H, McDermid, RM, Morganti, R, Naab, T, Oosterloo, T, Sarzi, M, Scott, N, Serra, P, Weijmans, A, Wong, T & Ott, J 2013, Quenching of Star Formation in Molecular Outflow Host NGC 1266. in IAU Symposium 292. Molecular Gas, Dust and Star Formation in Galaxies Proceedings IAU Symposium No. 292, 2012. pp. 371-371. https://doi.org/10.1017/S1743921313001725

TY - GEN

T1 - Quenching of Star Formation in Molecular Outflow Host NGC 1266

AU - Alatalo, K.

AU - Nyland, K. E.

AU - Graves, G.

AU - Deustua, S.

AU - Young, L. M.

AU - Davis, T. A.

AU - Crocker, A. F.

AU - Bureau, M.

AU - Bayet, E.

AU - Blitz, L.

AU - Bois, M.

AU - Bournaud, F.

AU - Cappellari, M.

AU - Davies, R. L.

AU - de Zeeuw, P. T.

AU - Emsellem, E.

AU - Khochfar, S.

AU - Krajnovic, D.

AU - Kuntschner, H.

AU - McDermid, R. M.

AU - Morganti, R.

AU - Naab, T.

AU - Oosterloo, T.

AU - Sarzi, M.

AU - Scott, N.

AU - Serra, P.

AU - Weijmans, A.

AU - Wong, Tony

AU - Ott, Jürgen

N1 - M1 - Conference Proceedings

PY - 2013/3

Y1 - 2013/3

N2 - We detail the rich molecular story of NGC 1266, its serendipitous discovery within the ATLAS3D survey (Cappellari et al. 2011) and how it plays host to an AGN-driven molecular outflow, potentially quenching all of its star formation (SF) within the next 100 Myr. While major mergers appear to play a role in instigating outflows in other systems, deep imaging of NGC 1266 as well as stellar kinematic observations from SAURON, have failed to provide evidence that NGC 1266 has recently been involved in a major interaction. The molecular gas and the instantaneous SF tracers indicate that the current sites of star formation are located in a hypercompact disk within 200 pc of the nucleus (Fig. 1; SF rate ≈ 2 M ⊙ yr-1). On the other hand, tracers of recent star formation, such as the Hβ absorption map from SAURON and stellar population analysis show that the young stars are distributed throughout a larger area of the galaxy than current star formation. As the AGN at the center of NGC 1266 continues to drive cold gas out of the galaxy, we expect star formation rates to decline as the star formation is ultimately quenched. Thus, NGC 1266 is in the midst of a key portion of its evolution and continued studies of this unique galaxy may help improve our understanding of how galaxies transition from the blue to the red sequence (Alatalo et al. 2011).

AB - We detail the rich molecular story of NGC 1266, its serendipitous discovery within the ATLAS3D survey (Cappellari et al. 2011) and how it plays host to an AGN-driven molecular outflow, potentially quenching all of its star formation (SF) within the next 100 Myr. While major mergers appear to play a role in instigating outflows in other systems, deep imaging of NGC 1266 as well as stellar kinematic observations from SAURON, have failed to provide evidence that NGC 1266 has recently been involved in a major interaction. The molecular gas and the instantaneous SF tracers indicate that the current sites of star formation are located in a hypercompact disk within 200 pc of the nucleus (Fig. 1; SF rate ≈ 2 M ⊙ yr-1). On the other hand, tracers of recent star formation, such as the Hβ absorption map from SAURON and stellar population analysis show that the young stars are distributed throughout a larger area of the galaxy than current star formation. As the AGN at the center of NGC 1266 continues to drive cold gas out of the galaxy, we expect star formation rates to decline as the star formation is ultimately quenched. Thus, NGC 1266 is in the midst of a key portion of its evolution and continued studies of this unique galaxy may help improve our understanding of how galaxies transition from the blue to the red sequence (Alatalo et al. 2011).

KW - galaxies: evolution

KW - galaxies: individual (NGC 1266)

KW - galaxies: active

UR - http://adsabs.harvard.edu/abs/2013IAUS..292..371A

U2 - 10.1017/S1743921313001725

DO - 10.1017/S1743921313001725

M3 - Conference contribution

SP - 371

EP - 371

BT - IAU Symposium 292. Molecular Gas, Dust and Star Formation in Galaxies Proceedings IAU Symposium No. 292, 2012

ER -

Quenching of Star Formation in Molecular Outflow Host NGC 1266

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