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GCN Circular 33819

LIGO/Virgo/KAGRA S230518h: AstroSat CZTI non-detection and upper limits
2023-05-18T20:42:47Z (a year ago)
Gaurav Waratkar at IIT Bombay <>
G. Waratkar (IITB), V. Bhalerao (IITB), M. Dixit (IITB), A. Ahmad (IITB), D. Bhattacharya (IUCAA), A. R. Rao (TIFR), S. Vadawale (PRL) report on behalf of the AstroSat CZTI collaboration:

We have carried out a search for X-ray candidates in AstroSat CZTI data in a 1000-sec window centered on the trigger time of the NSBH merger event candidate S230518h (UTC 2023-05-18 12:59:08, GCN Circular 33813). We use the Bilby.multiorder.fits,0 map (,0) for our analysis. CZTI is a coded aperture mask instrument that has a considerable effective area for about 29% of the entire sky and is also sensitive to brighter transients from the entire sky. At the time of the merger, AstroSat's nominal pointing is RA, DEC = 12:37:01.5, 14:12:34.4 (189.2562,14.2096), which is ~96 deg away from the maximum probability location. At the time of the merger event, the Earth-satellite-transient angle corresponding to the maximum probability location is ~43 deg and hence is occulted by Earth in the satellite's frame. The region of the localization map which is not occulted by Earth in the satellite's frame has a total probability of 0.26 (26%).

CZTI data were de-trended to remove orbit-wise background variation. We then searched data from the four independent, identical quadrants to look for coincident spikes in the count rates. Searches were undertaken by binning the data in 0.1s, 1s, and 10s respectively. Statistical fluctuations in background count rates were estimated by using data from 5 preceding orbits. We selected confidence levels such that the probability of a false trigger in a 1000 sec window is 10^-4. We do not find any evidence for any hard X-ray transient in this window, in the CZTI energy range of 20-200 keV.

We use a detailed mass model of the satellite to calculate the direction-dependent instrument response for points in the visible sky. We then assume the source is modeled as a power law with photon index alpha = -1, and convert our count rate upper limits to direction-dependent flux limits. We obtain the following upper limits for source flux in the 20-200 keV band by taking a probability-weighted mean over the visible sky:

0.1 s: flux limit= 2.01e-05 ergs/cm^2/s; fluence limit = 2.01e-06 ergs/cm^2
1.0 s: flux limit= 7.30e-06 ergs/cm^2/s; fluence limit = 7.30e-06 ergs/cm^2
10.0 s: flux limit= 8.25e-07 ergs/cm^2/s; fluence limit = 8.25e-06 ergs/cm^2

CZTI is built by a TIFR-led consortium of institutes across India, including VSSC, URSC, IUCAA, SAC, and PRL. The Indian Space Research Organisation funded, managed, and facilitated the project.

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