Extremely Large Telescope

A weak spectral signature of water vapour in the atmosphere of HD 179949 b at high spectral resolution in the L-band

(2020)

Authors:

Rebecca K Webb, Matteo Brogi, Siddharth Gandhi, Michael R Line, Jayne L Birkby, Katy L Chubb, Ignas AG Snellen, Sergey N Yurchenko

SDSS-IV MaNGA: The kinematic-morphology of galaxies on the mass vs star-formation relation in different environments

(2020)

Authors:

Bitao Wang, Michele Cappellari, Yingjie Peng, Mark Graham

Formation channels of slowly rotating early-type galaxies

(2020)

Authors:

Davor Krajnović, Ugur Ural, Harald Kuntschner, Paul Goudfrooij, Michael Wolfe, Michele Cappellari, Roger Davies, PT de Zeeuw, Pierre-Alain Duc, Eric Emsellem, Arna Karick, Richard M McDermid, Simona Mei, Thorsten Naab

Molecular gas inflows and outflows in ultraluminous infrared galaxies at z similar to 0.2 and one QSO at z=6.1

Astronomy and Astrophysics EDP Sciences 633 (2020) L4

Authors:

R Herrera-Camus, E Sturm, J Gracia-Carpio, S Veilleux, T Shimizu, D Lutz, M Stone, E Gonzalez-Alfonso, R Davies, J Fischer, R Genzel, R Maiolino, A Sternberg, L Tacconi, Aprajita Verma

Abstract:

Aims: Our aim is to search for and characterize inflows and outflows of molecular gas in four ultraluminous infrared galaxies (ULIRGs; LIR >  1012L⊙) at z ∼ 0.2−0.3 and one distant quasi-stellar object (QSO) at z = 6.13.

Methods: We used Herschel/PACS and ALMA Band 7 observations of the hydroxyl molecule (OH) line at rest-frame wavelength 119 μm, which in absorption can provide unambiguous evidence of inflows or outflows of molecular gas in nuclear regions of galaxies. Our study contributes to doubling the number of OH 119 μm observations of luminous systems at z ∼ 0.2−0.3, and pushes the search for molecular outflows based on the OH 119 μm transition to z ∼ 6.

Results: We detect OH 119 μm high-velocity absorption wings in three of the four ULIRGs. In two cases, IRAS F20036−1547 and IRAS F13352+6402, the blueshifted absorption profiles indicate the presence of powerful and fast (∼200−500 km s−1) molecular gas outflows. Consistent with an inside-out quenching scenario, these outflows are depleting the central reservoir of star-forming molecular gas at a rate similar to that of intense star formation activity. For the starburst-dominated system IRAS 10091+4704, we detect an inverted P Cygni profile that is unique among ULIRGs and indicates the presence of a fast (∼400 km s−1) inflow of molecular gas at a rate of ∼100 M⊙ yr−1 towards the central region. Finally, we tentatively detect (∼3σ) the OH 119 μm doublet in absorption in the z = 6.13 QSO ULAS J131911+095051. The OH 119 μm feature is blueshifted with a median velocity that suggests the presence of a molecular outflow, although characterized by a modest molecular mass loss rate of ∼200 M⊙ yr−1. This value is comparable to the small mass outflow rates found in the stacking of the [C II] spectra of other z ∼ 6 QSOs and suggests that ejective feedback in this phase of the evolution of ULAS J131911+095051 has subsided.

HARMONI - first light spectroscopy for the ELT: spectrograph camera lens mounts

Proceedings of SPIE - The International Society for Optical Engineering SPIE 11451 (2020)

Authors:

A Hidalgo, J Kariuki, J Lynn, W Cheng, A Lowe, Ft Bagci, F Clarke, I Lewis, I Tosh, H Schnetler, J Capone, M Tecza, M Booth, M Rodrigues, N Cann, N Thatte, Z Ozer, T Foster

Abstract:

HARMONI is the first light visible and near-infrared (NIR) integral field spectrograph for the Extremely Large Telescope(ELT). The HARMONI spectrograph will have four near-infrared cameras and two visible, both with seven lenses of various materials and diameters ranging from 286 to 152 mm. The lens mounts design has been optimized for each lens material to compensate for thermal stresses and maintain lens alignment at the operational temperature of 130 K. We discuss their design and mounting concept, as well as assembly and verification steps. We show initial results from two prototypes and outline improvements in the mounting procedures to reach tighter lens alignments. To conclude, we present a description of our future work to measure the decentering of the lenses when cooled down and settled.