Skip to main content
Testing. You are viewing the public testing version of GCN. For the production version, go to https://gcn.nasa.gov.
Announcing GCN Classic Migration Survey, End of Legacy Circulars Email. See news and announcements

GCN Circular 28903

Subject
IceCube-201114A: No counterpart candidates in INTEGRAL SPI-ACS and IBIS prompt observation
Date
2020-11-16T10:12:02Z (4 years ago)
From
Volodymyr Savchenko at ISDC,U of Geneve <savchenk@in2p3.fr>
V. Savchenko, C. Ferrigno (ISDC/UniGE, Switzerland)
J. Rodi (IAPS-Roma, Italy)
A. Coleiro (APC, France)
S. Mereghetti (INAF IASF-Milano, Italy)

on behalf of the INTEGRAL multi-messenger collaboration:
https://www.astro.unige.ch/cdci/integral-multimessenger-collaboration

Using combination of INTEGRAL all-sky detectors (following [1]):
SPI/ACS, IBIS/Veto, and IBIS  we have performed a search for a prompt
gamma-ray counterpart of IceCube-201114A (GCN 28887).

At the time of the event (2020-11-14 15:05:31 UTC, hereafter T0),
INTEGRAL was operating in nominal mode. The peak of the event
localization probability was at an angle of 73 deg with respect to the
spacecraft pointing axis. This orientation implies strongly suppressed
(24% of optimal) response of ISGRI, somewhat suppressed (42% of
optimal) response of IBIS/Veto, and near-optimal (87% of optimal)
response of SPI-ACS.

The background within +/-300 seconds around the event was stable 
(excess variance 1.2). 

We have performed a search for any impulsive events in INTEGRAL SPI-
ACS (as described in [2]), IBIS, and IBIS/Veto data.

We do not detect any significant counterparts and estimate a 3-sigma
upper limit on the 75-2000 keV fluence of 2.1e-07 erg/cm^2 (within the
50% probability containment region of the source localization) for a
burst lasting less than 1 s with a characteristic short GRB spectrum
(an exponentially cut off power law with alpha=-0.5 and Ep=600 keV)
occurring at any time in the interval within 300 s around T0. For a
typical long GRB spectrum (Band function with alpha=-1, beta=-2.5, and
Ep=300 keV), the derived peak flux upper limit is ~1.8e-07 (6.7e-08)
erg/cm^2/s at 1 s (8 s) time scale in 75-2000 keV energy range.

We report for completeness and in order of FAP, all excesses
identified in the search region. We find: 1 possibly associated
excess:

T-T0     | scale   | S/N | flux ( x 1e-06 erg/cm2/s)     | FAP    
-76.3    | 9.35    | 3.7 |    0.855 +/- 0.21   +/- 0.21   | 0.0411 

9 likely background excesses:

T-T0     | scale   | S/N | flux ( x 1e-06 erg/cm2/s)     | FAP    
-3.14    | 0.1     | 3.7 |    0.803 +/- 0.206  +/- 0.197  | 0.161 
20.6     | 0.15    | 4   |    0.724 +/- 0.168  +/- 0.178  | 0.43  
-6.14    | 0.1     | 3.3 |    0.717 +/- 0.206  +/- 0.176  | 0.712 
-95.7    | 0.05    | 6.5 |     2.05 +/- 0.3    +/- 0.505  | 0.714 
-287     | 1.95    | 3.7 |     1.95 +/- 0.462  +/- 0.479  | 0.761 
18.2     | 0.3     | 3.2 |     4.05 +/- 1.18   +/- 0.995  | 0.855 
-118     | 1.7     | 3.2 |     1.72 +/- 0.494  +/- 0.423  | 0.937 
16.8     | 0.15    | 3.4 |    0.609 +/- 0.168  +/- 0.15   | 0.963 
36       | 0.75    | 3.1 |     2.47 +/- 0.745  +/- 0.606  | 0.99  

Note that FAP estimates (especially at timescales above 2s) may be
possibly further affected by enhanced non-stationary local background
noise. This list excludes any excesses for which FAP is close to
unity.



All results quoted are preliminary.

This circular is an official product of the INTEGRAL Multi-Messenger
team.

[1] Savchenko et al. 2017, A&A 603, A46 
[2] Savchenko et al. 2012, A&A 541A, 122S

--
Looking for U.S. government information and services? Visit USA.gov