A dataset provided by the European Space Agency

Name DEBRIS40
Title Dust Debris Around Solar Mass Stars
URL

http://nida.esac.esa.int/nida-sl-tap/data?RETRIEVAL_TYPE=OBSERVATION&PRODUCT_LEVEL=ALL&obsno=663003020

DOI https://doi.org/10.5270/esa-sf5so1d
Author Becklin, E.E.
Description scientific abstract with iso, we propose to study the physical nature and evolutionary history of dust debris clouds around solar mass stars. these clouds, discovered by iras, are thought to be related to planetary systems. the program will consist of: (i) a photometric study of selected a, f, g, and k-type main sequence stars within 20 pc of the sun. 100 stars have been selected with various ages and multiplicity. (ii) a study of the evolutionary history of debris clouds from observations of virgul140 young open cluster stars and weak-line t tauri stars. (iii) search for excess emission from virgul20 known young main sequence field stars beyond 20 pc. (iv) search for possible dust disks around degenerate stars. the investigation will clarify the relationship of the debris clouds, specific properties of stars, and place the phenomenon in the context of planetary formation. observation summary we will investigate the excess emission from main sequence stars at 60 micron and 100 micron using c100 and p3 in isophot. for the cluster stars we will use a sparse map and c100 (pht37, pht38, and pht39). each observation consists of a single stare on the object and then a corresponding stare on an adjacent sky, separated by 2 arcmin. for stability of the detectors, all observations in a sequence will be done at one wavelength and then a repeated reverse sequence at a second wavelength; the two sequences are concatenated together. integration times on each of the source and sky will be 160 sec at 60 micron and 96 sec at 100 micron. the required signal to noise for these cluster stars is unknown, since the photosphere will not be seen and the amount of excess depends on the unknown dust density. for measurements of field stars and isolated cluster stars, either the photometer p3 or array c100 will be used, depending on the cirrus noise. if cirrus > 15 mjy/sr at 100 micron, c100 is used. in both cases... a triangular wave chopping will be used. the peak to peak motion of the chopper throw will be 270 arcsec with the object in the center (the object will thus be 135 arcsec from each extreme position). integration times on source will typically be 128 sec at 60 micron and 64 sec at 100 micron. the 99 arcsec aperture will be used for the p3 observations with anticipated high s/n. the remaining p3 observations will be made with the 79 arcsec aperture. we expect that the photosphere will be detected for most stars stars with a s/n > 5. acquisition\t\t\t180 sec initial instrument setup\t 15 sec stability of detector\t\t 90 sec filter change (2 pos)\t\t 20 sec fcs exposures (for 2 filters)\t 32 sec integration at 60 micron\t384 sec integration at 100 micron\t128 sec total time\t\t\t849 sec
Instrument CAM01
Temporal Coverage 1997-09-02T08:07:10Z/1997-12-16T03:55:39Z
Version 1.0
Mission Description The Infrared Space Observatory (ISO) was the world's first true orbiting infrared observatory. Equipped with four highly-sophisticated and versatile scientific instruments, it was launched by Ariane in November 1995 and provided astronomers world-wide with a facility of unprecedented sensitivity and capabilities for a detailed exploration of the Universe at infrared wavelengths.
Creator Contact https://support.cosmos.esa.int/iso/
Date Published 1999-06-04T00:00:00Z
Publisher And Registrant European Space Agency
Credit Guidelines European Space Agency, Becklin, E.E., 1999, DEBRIS40, 1.0, European Space Agency, https://doi.org/10.5270/esa-sf5so1d