B. Lefloch, S. Cabrit, G. Busquet, C. Codella, C. Ceccarelli, J. Cernicharo, J. R. Pardo, M. Benedettini, D. C. Lis, B. Nisini
The unprecedented sensitivity of Herschel coupled with the high resolution of the HIFI spectrometer permits studies of the intensity-velocity relationship I(v) in molecular outflows, over a higher excitation range than possible up to now. In the course of the CHESS Key Program, we have observed toward the bright bowshock region L1157-B1 the CO rotational transitions between J=5-4 and J=16-15 with HIFI, and the J=1-0, 2-1 and 3-2 with the IRAM-30m and the CSO telescopes. We find that all the line profiles I_{CO}(v) are well fit by a linear combination of three exponential laws exp(-|v/v_0|) with v_0= 12.5, 4.4 and 2.5km/s. The first component dominates the CO emission at J_up > 13, as well as the high-excitation lines of SiO and H2O. The second component dominates for 3 < J_up < 10 and the third one for J_up < 2. We show that these exponentials are the signature of quasi-isothermal shocked gas components: the impact of the jet against the L1157-B1 bowshock (T= 210K), the walls of the outflow cavity associated with B1 (T= 64K) and the older cavity L1157-B2 (T= 23K), respectively. Analysis of the CO line flux in the Large-Velocity Gradient approximation further shows that the emission arises from dense gas (n(H2) > 1e5-1e6 cm-3) close to LTE up to J=20. We find that the CO J=2-1 intensity-velocity relation observed in various other molecular outflows is satisfactorily fit by similar exponential laws, which may hold an important clue to their entrainment process.
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http://arxiv.org/abs/1208.4140
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