The L1157-B1 astrochemical laboratory: testing the origin of DCN

L1157-B1 is the brightest shocked region of the large-scale molecular outflow, considered the prototype of chemically rich outflows, being the ideal laboratory to study how shocks affect the molecular gas. Several deuterated molecules have been previously detected with the IRAM 30m, most of them formed on grain mantles and then released into the gas phase due to the shock. We aim to observationally investigate the role of the different chemical processes at work that lead to formation the of DCN and test the predictions of the chemical models for its formation. We performed high-angular resolution observations with NOEMA of the DCN(2-1) and H13CN(2-1) lines to compute the deuterated fraction, Dfrac(HCN). We detected emission of DCN(2-1) and H13CN(2-1) arising from L1157-B1 shock. Dfrac(HCN) is ~4x10$^{-3}$ and given the uncertainties, we did not find significant variations across the bow-shock. Contrary to HDCO, whose emission delineates the region of impact between the jet and the ambient material, DCN is more widespread and not limited to the impact region. This is consistent with the idea that gas-phase chemistry is playing a major role in the deuteration of HCN in the head of the bow-shock, where HDCO is undetected as it is a product of grain-surface chemistry. The spectra of DCN and H13CN match the spectral signature of the outflow cavity walls, suggesting that their emission result from shocked gas. The analysis of the time dependent gas-grain chemical model UCL-CHEM coupled with a C-type shock model shows that the observed Dfrac(HCN) is reached during the post-shock phase, matching the dynamical timescale of the shock. Our results indicate that the presence of DCN in L1157-B1 is a combination of gas-phase chemistry that produces the widespread DCN emission, dominating in the head of the bow-shock, and sputtering from grain mantles toward the jet impact region.

[1]  S. Viti,et al.  UCLCHEM: A Gas-grain Chemical Code for Clouds, Cores, and C-Shocks , 2017, 1705.10677.

[2]  B. Lefloch,et al.  Silicon-bearing molecules in the shock L1157-B1: first detection of SiS around a Sun-like protostar , 2017, 1705.01794.

[3]  S. Viti,et al.  Phosphorus-bearing molecules in solar-type star-forming regions: first PO detection , 2016, 1608.00048.

[4]  P. Hennebelle,et al.  First image of the L1157 molecular jet by the CALYPSO IRAM-PdBI survey , 2016, 1608.05026.

[5]  S. Viti,et al.  H2S in the L1157-B1 bow shock , 2016, 1608.01983.

[6]  G. Blake,et al.  CSO AND CARMA OBSERVATIONS OF L1157. II. CHEMICAL COMPLEXITY IN THE SHOCKED OUTFLOW , 2016, 1605.09707.

[7]  Stephan Schlemmer,et al.  The Cologne Database for Molecular Spectroscopy, CDMS, in the Virtual Atomic and Molecular Data Centre, VAMDC , 2016, 1603.03264.

[8]  S. Viti,et al.  Astrochemistry at work in the L1157-B1 shock: acetaldehyde formation , 2014, 1412.8318.

[9]  S. Viti,et al.  The density structure of the L1157 molecular outflow , 2014, 1410.8453.

[10]  S. Viti,et al.  THE L1157–B1 ASTROCHEMICAL LABORATORY: MEASURING THE TRUE FORMALDEHYDE DEUTERATION ON GRAIN MANTLES , 2014 .

[11]  C. Ceccarelli,et al.  Molecular ions in the protostellar shock L1157-B1 , 2014, 1402.2329.

[12]  Astronomy,et al.  The CHESS survey of the L1157-B1 bow-shock: high and low excitation water vapor , 2013, 1311.2840.

[13]  S. Viti,et al.  The B1 shock in the L1157 outflow as seen at high spatial resolution , 2013, 1309.0433.

[14]  J. Goicoechea,et al.  Combined IRAM and Herschel/HIFI study of cyano(di)acetylene in Orion KL: tentative detection of DC3N , 2013, 1309.0446.

[15]  P. Caselli,et al.  BROAD N2H+ EMISSION TOWARD THE PROTOSTELLAR SHOCK L1157-B1 , 2013, 1308.6478.

[16]  M. Gerin,et al.  CH2D(+), the search for the holy grail. , 2013, The journal of physical chemistry. A.

[17]  P. Caselli,et al.  ERRATUM: “THE HERSCHEL AND IRAM CHESS SPECTRAL SURVEYS OF THE PROTOSTELLAR SHOCK L1157-B1: FOSSIL DEUTERATION” (2012, ApJ, 757, L9) , 2012 .

[18]  P. Caselli,et al.  THE HERSCHEL AND IRAM CHESS SPECTRAL SURVEYS OF THE PROTOSTELLAR SHOCK L1157-B1: FOSSIL DEUTERATION , 2012 .

[19]  J. Cernicharo,et al.  THE CHESS SURVEY OF THE L1157-B1 SHOCK REGION: CO SPECTRAL SIGNATURES OF JET-DRIVEN BOW SHOCKS , 2012, 1208.4140.

[20]  C. Ceccarelli,et al.  FORMALDEHYDE AND METHANOL DEUTERATION IN PROTOSTARS: FOSSILS FROM A PAST FAST HIGH-DENSITY PRE-COLLAPSE PHASE , 2012, 1202.3073.

[21]  A. Giorgio,et al.  The CHESS survey of the L1157-B1 shock: the dissociative jet shock as revealed by Herschel–PACS , 2012, 1202.1451.

[22]  P. Caselli,et al.  L1157-B1: WATER AND AMMONIA AS DIAGNOSTICS OF SHOCK TEMPERATURE , 2011, 1108.2892.

[23]  B. Nisini,et al.  Water cooling of shocks in protostellar outflows: Herschel-PACS map of L1157 , 2010, 1005.4517.

[24]  A. Fuente,et al.  Methyl cyanide as tracer of bow shocks in L1157-B1 , 2009 .

[25]  È. Roueff,et al.  Deuterium chemistry in the Orion Bar PDR - “Warm” chemistry starring CH2D+ , 2009, 0909.4683.

[26]  M. Asplund,et al.  The chemical composition of the Sun , 2009, 0909.0948.

[27]  Spain.,et al.  Parametrization of C-shocks. Evolution of the sputtering of grains , 2008, 0802.0594.

[28]  J. Tobin,et al.  A Flattened Protostellar Envelope in Absorption around L1157 , 2007, 0710.2314.

[29]  S. Viti,et al.  The clumpy structure of the chemically active L1157 outflow , 2007, 0708.0133.

[30]  T. Millar,et al.  The UMIST database for astrochemistry 2012 , 2012, 1212.6362.

[31]  J. Black,et al.  A computer program for fast non-LTE analysis of interstellar line spectra With diagnostic plots to interpret observed line intensity ratios , 2007, 0704.0155.

[32]  È. Roueff,et al.  Deuterium fractionation in warm dense interstellar clumps , 2007 .

[33]  European Southern Observatory,et al.  APEX 1 mm line survey of the Orion Bar , 2006, astro-ph/0605714.

[34]  Holger S. P. Müller,et al.  The Cologne Database for Molecular Spectroscopy, CDMS: a useful tool for astronomers and spectroscopists , 2005 .

[35]  S. Viti,et al.  Evaporation of ices near massive stars: models based on laboratory temperature programmed desorption data , 2004, astro-ph/0406054.

[36]  P. Caselli,et al.  Molecular Ions in L1544. II. The Ionization Degree , 2001, astro-ph/0109023.

[37]  R. Bachiller,et al.  Chemically active outflow L 1157 , 2001 .

[38]  Holger S. P. Müller,et al.  THE COLOGNE DATABASE FOR MOLECULAR SPECTROSCOPY, CDMS , 2001 .

[39]  M. P. Gutiérrez,et al.  Shock Chemistry in the Young Bipolar Outflow L1157 , 1997 .

[40]  J. M. C. Rawlings,et al.  Direct diagnosis of infall in collapsing protostars – I. The theoretical identification of molecular species with broad velocity distributions , 1992 .

[41]  T. Wilson,et al.  Abundances in the interstellar medium , 1992 .

[42]  W. D. Watson Gas Phase Reactions in Astrophysics , 1978 .

[43]  M. Melchior,et al.  UvA-DARE ( Digital Academic Repository ) Herschel spectral surveys of star-forming regions : Overview of the 555-636 GHz range , 2010 .

[44]  E. F. Dishoeck,et al.  Chemical evolution of star-forming regions. , 1998, Annual review of astronomy and astrophysics.