Odin observations of water in molecular outflows and shocks

et al. 2010

A&A

Context. L1448-mm is the prototype of a low-mass Class 0 protostar driving a high-velocity jet. Given its bright H 2 O spectra observed with ISO, L1448-mm is an ideal laboratory to observe heavy water (HDO) emission. Aims. Our aim is to image the HDO emission in the protostar surroundings, the possible occurrence of HDO emission also investigating off L1448-mm, towards the molecular outflow. Methods. We carried out observations of L1448-mm in the HDO(1 10 -1 11 ) line at 80.6 GHz, an excellent tracer of HDO column density, with the IRAM Plateau de Bure Interferometer. Results. We image for the first time HDO emission around L1448-mm. The HDO structure reveals a main clump at velocities close to the ambient one towards the the continuum peak that is caused by the dust heated by the protostar. In addition, the HDO map shows tentative weaker emission at 2000 AU from the protostar towards the south, which is possibly associated with the walls of the outflow cavity opened by the protostellar wind. Conclusions. Using an LVG code, modelling the density and temperature profile of the hot-corino, and adopting a gas temperature of 100 K and a density of 1.5 × 10 8 cm −3 , we derive a beam diluted HDO column density of ∼7 × 10 13 cm −2 , corresponding to a HDO abundance of ∼4 × 10 −7 . In addition, the present map supports the scenario where HDO can be efficiently produced in shocked regions and not uniquely in hot corinos heated by the newly born star.

Section: Introductionmentioning

confidence: 98%

Heavy water around the L1448-mm protostar

Codella

Ceccarelli

et al. 2010

A&A

“…Following ISO, the SWAS and Odin facilities made it possible to observe the ortho-H 2 Ofundamental line at 557 GHz, providing important constraints on the water abundance and kinematics in the cold outflow gas components (e.g., Franklin et al 2008;Bjerkeli et al 2009). All these facilities, however, had poor spatial resolution (i.e.…”

Section: Introductionmentioning

confidence: 99%

Water cooling of shocks in protostellar outflows

Benedettini²,

Codella³

et al. 2010

A&A

Self Cite

Context. The far-IR/sub-mm spectral mapping facility provided by the Herschel-PACS and HIFI instruments has made it possible to obtain, for the first time, images of H 2 O emission with a spatial resolution comparable to ground based mm/sub-mm observations. Aims. In the framework of the Water In Star-forming regions with Herschel (WISH) key program, maps in water lines of several outflows from young stars are being obtained, to study the water production in shocks and its role in the outflow cooling. This paper reports the first results of this program, presenting a PACS map of the o-H 2 O 179 μm transition obtained toward the young outflow L1157. Methods. The 179 μm map is compared with those of other important shock tracers, and with previous single-pointing ISO, SWAS, and Odin water observations of the same source that allow us to constrain the H 2 O abundance and total cooling. Results. Strong H 2 O peaks are localized on both shocked emission knots and the central source position. The H 2 O 179 μm emission is spatially correlated with emission from H 2 rotational lines, excited in shocks leading to a significant enhancement of the water abundance. Water emission peaks along the outflow also correlate with peaks of other shock-produced molecular species, such as SiO and NH 3 . A strong H 2 O peak is also observed at the location of the proto-star, where none of the other molecules have significant emission. The absolute 179 μm intensity and its intensity ratio to the H 2 O 557 GHz line previously observed with Odin/SWAS indicate that the water emission originates in warm compact clumps, spatially unresolved by PACS, having a H 2 O abundance of the order of 10 −4 . This testifies that the clumps have been heated for a time long enough to allow the conversion of almost all the available gas-phase oxygen into water. The total H 2 O cooling is ∼10 −1 L , about 40% of the cooling due to H 2 and 23% of the total energy released in shocks along the L1157 outflow.

“…The positioning of the slits adopted for VLT/VISIR and CRIRES observations is shown in blue and red. The beam sizes of Herschel H 2 O (2 12 −1 01 ) (magenta circle), CO (15−14) (green, Bjerkeli et al 2014), and SEST CO (2−1) (black, Bjerkeli et al 2009Bjerkeli et al , 2011 are displayed. Offsets are relative to: α J2000 = 12 h 55 m 50. s 3, δ J2000 = −76 • 56 23 (Bjerkeli et al 2011).…”

Section: Visir High-resolution Mid-ir Spectroscopymentioning

confidence: 99%

“…The comparison between H 2 0−0 S(4) at HH 54C1/C2 and H 2 O (2 12 −1 01 ), CO (15−14) (Bjerkeli et al 2014), and CO (2−1) (Bjerkeli et al 2009(Bjerkeli et al , 2011 observations at HH 54B is presented in the lower panel of Fig. 2.…”

Section: Two Velocity Components In H 2 Observationsmentioning

confidence: 99%

“…Caratti o Garatti et al 2006;Ybarra & Lada 2009;Bjerkeli et al 2011). Mid-IR cooling is dominated by pure rotational H 2 lines (Cabrit et al 1999;Giannini et al 2006;Neufeld et al 1998Neufeld et al , 2006 probing warm gas with a mixture of temperatures in the range 400−1200 K. HH 54 was also observed in several lines of CO and H 2 O from space and the ground (Liseau et al 1996;Nisini et al 1996;Bjerkeli et al 2009Bjerkeli et al , 2011.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

First spectrally-resolved H₂observations towards HH 54

Santangelo

Antoniucci

et al. 2014

A&A

Self Cite

Context. Herschel observations suggest that the H 2 O distribution in outflows from low-mass stars resembles the H 2 emission. It is still unclear which of the different excitation components that characterise the mid-and near-IR H 2 distribution is associated with H 2 O. Aims. The aim is to spectrally resolve the different excitation components observed in the H 2 emission. This will allow us to identify the H 2 counterpart associated with H 2 O and finally derive directly an H 2 O abundance estimate with respect to H 2 . Methods. We present new high spectral resolution observations of H 2 0−0 S(4), 0−0 S(9), and 1−0 S(1) towards HH 54, a bright nearby shock region in the southern sky. In addition, new Herschel/HIFI H 2 O (2 12 −1 01 ) observations at 1670 GHz are presented. Results. Our observations show for the first time a clear separation in velocity of the different H 2 lines: the 0−0 S(4) line at the lowest excitation peaks at −7 km s −1 , while the more excited 0−0 S(9) and 1−0 S(1) lines peak at −15 km s −1 . H 2 O and high-J CO appear to be associated with the H 2 0−0 S(4) emission, which traces a gas component with a temperature of 700−1000 K. The H 2 O abundance with respect to H 2 0−0 S(4) is estimated to be X(H 2 O) < 1.4 × 10 −5 in the shocked gas over an area of 13 . Conclusions. We resolve two distinct gas components associated with the HH 54 shock region at different velocities and excitations. This allows us to constrain the temperature of the H 2 O emitting gas (≤1000 K) and to derive correct estimates of H 2 O abundance in the shocked gas, which is lower than what is expected from shock model predictions.