Difference between revisions of "Wendi's table of all data sources"

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|X-ray
 
|X-ray
 
|X-rays trace stellar magnetic activity, can reduce number of foreground/background objects by requiring X-ray detections. Young stars are bright in X-rays because they are rotating quickly and therefore flaring a lot.  
 
|X-rays trace stellar magnetic activity, can reduce number of foreground/background objects by requiring X-ray detections. Young stars are bright in X-rays because they are rotating quickly and therefore flaring a lot.  
|25 Gloubule sources identified as YSOs in the center. 117 sources tabulated in Table 1. Also, entire Nisini catalog included in Table 3. (Nisini is deeper JHK than 2MASS.) SEDs in Figure 5 good for comparison to ours.
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|25 Globule sources identified as YSOs in the center. 117 sources tabulated in Table 1. Also, entire Nisini catalog included in Table 3. (Nisini is deeper JHK than 2MASS.) SEDs in Figure 5 good for comparison to ours.
 
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|Choudhury et al. 2010
 
|Choudhury et al. 2010

Revision as of 21:44, 22 May 2013

Finding cluster members, originally known as "Luisa’s Table of Characteristics of Young Stars for Determining Cluster Members", may be of some interest.

The table

Wendi's table orignally included (data) source, type (wavelength), and reasoning. Anything else to add?

Data source Wavelength(s) Why we should care Additional notes on this data source
Getman et al. 2007 X-ray X-rays trace stellar magnetic activity, can reduce number of foreground/background objects by requiring X-ray detections. Young stars are bright in X-rays because they are rotating quickly and therefore flaring a lot. 25 Globule sources identified as YSOs in the center. 117 sources tabulated in Table 1. Also, entire Nisini catalog included in Table 3. (Nisini is deeper JHK than 2MASS.) SEDs in Figure 5 good for comparison to ours.
Choudhury et al. 2010 optical (including Halpha, IRAC, MIPS, 2MASS), some spectra (from which they got spectral types) very similar data sets, and analysis (at least to aspire to), though over a smaller area, and certainly seems to be reliable in terms of data reduction and coordinate accuracy. Identified 118 sources, 40 YSOs+13 candidates. published whole table.
Chauhan et al. 2009 BVI, IRAC identified only 18 sources, but still useful, also over small region. Experience in BRC 27 with this paper suggests we need to be cautious with their data tables. Check to make sure sources really match. published just the YSOs.
Ogura et al. 2002 Halpha = 6563 A because young accreting stars are bright in Halpha We have updated the coordinates for the BRC 38 sources listed. Also note that they have finding charts of their sources, and of the HH sources they have identified here. Objects tabulated in this paper with small Ha EQWs are probably just chromospheric activity and not accretion.
Barentsen et al. 2011
IPHAS
Nakano et al. 2012
2MASS JHKs over whole region, not just a subset point sources can be matched across bands over whole region!
Beltran et al. 2009 NIR (JHK') and H2 (1.2-2.2 um) (deeper than 2MASS!) link the point sources across all available bands; look for complex H2 structures, unclear if we will find them. Further data on BIMA 1,2,3 and Source C
WISE
AKARI
Spitzer

Areas covered (from our proposal)

Ccwelpropfig4.png

Figure 4: This WISE-4 (22μm) greyscale image of the BRC 38 region (~40’ on a side) is the region of proposed study; the green circle is 20’ in radius (~40’ diameter). The central green square is the region covered by all four Spitzer IRAC bands. The green dashed-line square to the lower left is the serendipitous IRAC 2 & 4 (4.8 & 8 μm) data and the green dashed-line square in the upper right is the serendipitous IRAC 1 & 3 (3.6 & 5.8 μm) data. The red square shows the Spitzer MIPS -24 μm coverage and the red rectangle is MIPS-70 μm coverage. The large blue box in the center is the Chandra field of view for the observation discussed in Getman et al. (2007). The optical data from Chauhan et al. (2011), Choudhury et al. (2010), and Ogura et al. (2002) are largely within the region of IRAC 4-band coverage. The deep JHK data from Beltrán et al. (2009) are in a region comparable to the IRAC 4-band coverage.