H. S. Liszt and J. Pety: Imaging diffuse clouds: bright and dark gas mapped in CO<strong>tel</strong>-<strong>00726959</strong>, version 1 - 31 Aug 2012Assessing the contribution of diffuse gas at lower latitudes awaitsa wider examination of the character of the gas seen in the galacticdisk, but the contribution of diffuse mo<strong>le</strong>cular gas in the innergalactic disk is apparent in recent HERSCHEL/PRISMASobservations of sub-mm absorption spectra toward star-formingregions (Gerin et al. 2010; Sonnentrucker et al. 2010).10. Summary and conclusionsWe compared maps of CO emission with reddening maps on atypical field of view of about 30 ′ × 30 ′ at an angular resolutionof 1 ′ toward 11 diffuse lines of sight for which we already hadsub-arcsec mo<strong>le</strong>cular and/or atomic absorption profi<strong>le</strong>s. This allowedus to draw three kinds of conclusions.10.1. Conclusions about the position-position-velocitystructure of the emission– Although most of the CO emission structure was amorphousor merely blob-like when mapped, the emission aroundB0528+138 was found to be highly regular and quasiperiodicwhi<strong>le</strong> that around B2200+420 (BL Lac) was seento be filamentary and tang<strong>le</strong>d.– Toward B0355+508 and B0528+134, CO mapping suggeststhat pairs of absorption lines separated by 6−8 kms −1 arephysically related, not merely accidental superpositions.– CO mapping shows that partition of an absorption profi<strong>le</strong>into kinematic components, no matter how seemingly obvious,may actually be arbitrary and capricious: the decompositionmay have no apparent validity in emission at positionsonly slightly removed from the continuum background.10.2. Conclusions linking the absorption to the emissionkinematics– The same clouds were seen in absorption and emission, andin atomic and mo<strong>le</strong>cular phases, although not necessarilyin the same location. We fai<strong>le</strong>d to find CO emission correspondingto just one out of 20 mo<strong>le</strong>cular absorption features,in one relatively small spatial field, i.e. 20 ′ × 20 ′ vs. 30 ′ × 30 ′or more. Conversely, whi<strong>le</strong> mapping away from the continuumbackground we saw only 2 CO emission features lackingmo<strong>le</strong>cular absorption counterparts.– CO emission was sometimes found in the field at velocitiescorresponding to features seen only in H I absorption towardthe continuum. We saw no mo<strong>le</strong>cular features outside thespan of the H I absorption.10.3. Conclusions regarding the CO luminosity of diffuse gas– We found relatively bright CO emission at modest reddeningin the fields we mapped, with peak brightnesses of 4−5KatE B−V< ∼ 0.15 mag and up to 10−12 K at E B−V ≃ 0.3 mag(i.e. A V ≃ 1 mag). This was true even for features that wereseen only in absorption toward the continuum source in thefield center.– The CO emission lines represent small column densitiesN(CO) ≤ 10 16 cm −2 , <strong>le</strong>ss than 10% of the amount offree gas phase carbon expected along a line of sight withE B−V = 0.15 mag or A V = 0.5 mag. The dominant form ofgas phase carbon is still C + .– When CO emission was detected at <strong>le</strong>vels of 1.5 K km s −1and higher, it was generally over-luminous in the senseof having a small ratio N(H 2 )/W CO , i.e. a value of theCO-H 2 conversion factor below 2 × 10 20 H 2 (K km s −1 ) −1 .W CO /N(H 2 ) ratios as small as N(H 2 )/W CO< ∼ 5 ×10 19 cm −2 H 2 (km s −1 ) −1 are mandated by the observed reddeningin cases where the line of sight was relatively free ofextraneous material.– On average, the W CO /N(H 2 ) ratio in diffuse gas is locally thesame as in dense fully mo<strong>le</strong>cular clouds despite the presenceof strong variations between individual diffuse gas parcels orsightlines. The global W CO /N(H 2 ) ratio in diffuse gas is theresult of averaging over limited regions where CO emissionis readily detectab<strong>le</strong> and overly bright (in the sense of havingW CO /N(H 2 ) much higher than the mean), and with other regionshaving a significant mo<strong>le</strong>cular component (as seen inabsorption) but where CO emission is comparatively weakor simply undetectab<strong>le</strong>.– Small W CO /N(H 2 ) ratios and sharp variations in theW CO /E B−V ratio are not artifacts of the disparity in resolutionbetween the 1 ′ CO emission beam and the 6 ′ resolution ofthe reddening maps, because high CO brightnesses and smallW CO /E B−V ratios persist when the resolution of the CO mapsis degraded to that of the reddening maps.– Sharp variations in the CO emission brightness on arcminutesca<strong>le</strong>s do not necessarily represent unresolved structure inthe reddening maps or in the column density of H or H 2 .Detectab<strong>le</strong> CO emission generally arises in the regime whereW CO ∝ N(CO), and variations in the line brightness representprimarily the CO chemistry with its extreme sensitivityto E B−V and N(H 2 ). Secondarily the line brightness is influencedby CO rotational excitation since some features arenot seen in emission toward continuum sources where thereis CO absorption with appreciab<strong>le</strong> optical depth.– Only marginally does the CO brightness represent the underlyingmass or H 2 column density distribution of diffusemo<strong>le</strong>cular gas.Acknow<strong>le</strong>dgements. The National Radio Astronomy Observatory is operated byAssociated Universites, Inc. under a cooperative agreement with the US NationalScience Foundation. The Kitt Peak 12-m millimetre wave <strong>tel</strong>escope is operatedby the Arizona Radio Observatory (ARO), Steward Observatory, University ofArizona. IRAM is operated by CNRS (France), the MPG (Germany) and the IGN(Spain). This work has been partially funded by the grant ANR-09-BLAN-0231-01 from the French Agence Nationa<strong>le</strong> de la Recherche as part of the SCHISMproject (http://schism.ens.fr/). 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