Difference between revisions of "EGAL02"
(→Proposal) |
(→Proposal) |
||
| (33 intermediate revisions by the same user not shown) | |||
| Line 2: | Line 2: | ||
Proposal: [[Media:EGAL02_Nozaki.pdf|EGAL02:Observations of distant bright FSRQs in active states]] <br> | Proposal: [[Media:EGAL02_Nozaki.pdf|EGAL02:Observations of distant bright FSRQs in active states]] <br> | ||
PI: Seiya Nozaki (nozaki@mpp.mpg.de) <br> | PI: Seiya Nozaki (nozaki@mpp.mpg.de) <br> | ||
| + | |||
| + | Source: 3C454.3 <br> | ||
| + | RA (J2000) 343.49061685 deg <br> | ||
| + | DEC (J2000) 16.14821153 deg <br> | ||
Source: Ton599 <br> | Source: Ton599 <br> | ||
| − | RA (J2000) 179.88264131 <br> | + | RA (J2000) 179.88264131 deg <br> |
| − | DEC (J2000) 29.24550745 <br> | + | DEC (J2000) 29.24550745 deg <br> |
=== Observational settings/limits === | === Observational settings/limits === | ||
| − | - | + | - 3C454.3 |
| − | + | The observations should be organized through the ToO form when the integral photon flux (>100 MeV) reaches 1×10−5 cm−2 s−1. | |
| − | + | In this state, LST-1 is expected to detect low-energy gamma-ray signals with ∼30 hours of observations. | |
| + | If we detect a significant flare and the integral photon flux is still above the mentioned threshold after the flare, we also request another 30 hours of observations after the flare | ||
| − | - | + | - Ton 599 |
| + | |||
| + | we request 50 hours of observations unless the average integral photon flux (>100 MeV) goes down below 0.5×10−6 cm−2 s−1 | ||
| + | |||
| + | '''It seems the gamma-ray spectrum of Ton 599 is sometimes hard (<2.0) (especially since April) and variable. So even when integral photon flux above 100 MeV is below the original limit (0.5x10-6 cm-2 s-1), there is a possibility to detect this source. When the spectrum is hard enough (e.g. April 23, 2023), it is detectable for a short observation. Thus, we want to request to schedule short exposure observations (1-2 hours) for monitoring purposes, rather than longer exposure for less nights, when this source can be scheduled (=no collision with other higher priority tasks/sources). If we detect some signs of active state (e.g. high energy photons), we will contact schedulers.''' | ||
| + | |||
| + | == Analysis == | ||
| + | - Summary (Ton599) | ||
https://docs.google.com/presentation/d/1gaDXn9cRdHN7RWg4m9iZqNLSwOAlH4m0W2f5V8CqSI8/edit?usp=sharing | https://docs.google.com/presentation/d/1gaDXn9cRdHN7RWg4m9iZqNLSwOAlH4m0W2f5V8CqSI8/edit?usp=sharing | ||
| + | |||
| + | - wiki page | ||
| + | -- https://www.lst1.iac.es/wiki/index.php/TON599 | ||
| + | -- https://www.lst1.iac.es/wiki/index.php/3C454.3 | ||
Latest revision as of 11:23, 17 January 2024
Proposal[edit]
Proposal: EGAL02:Observations of distant bright FSRQs in active states
PI: Seiya Nozaki (nozaki@mpp.mpg.de)
Source: 3C454.3
RA (J2000) 343.49061685 deg
DEC (J2000) 16.14821153 deg
Source: Ton599
RA (J2000) 179.88264131 deg
DEC (J2000) 29.24550745 deg
Observational settings/limits[edit]
- 3C454.3
The observations should be organized through the ToO form when the integral photon flux (>100 MeV) reaches 1×10−5 cm−2 s−1. In this state, LST-1 is expected to detect low-energy gamma-ray signals with ∼30 hours of observations. If we detect a significant flare and the integral photon flux is still above the mentioned threshold after the flare, we also request another 30 hours of observations after the flare
- Ton 599
we request 50 hours of observations unless the average integral photon flux (>100 MeV) goes down below 0.5×10−6 cm−2 s−1
It seems the gamma-ray spectrum of Ton 599 is sometimes hard (<2.0) (especially since April) and variable. So even when integral photon flux above 100 MeV is below the original limit (0.5x10-6 cm-2 s-1), there is a possibility to detect this source. When the spectrum is hard enough (e.g. April 23, 2023), it is detectable for a short observation. Thus, we want to request to schedule short exposure observations (1-2 hours) for monitoring purposes, rather than longer exposure for less nights, when this source can be scheduled (=no collision with other higher priority tasks/sources). If we detect some signs of active state (e.g. high energy photons), we will contact schedulers.
Analysis[edit]
- Summary (Ton599) https://docs.google.com/presentation/d/1gaDXn9cRdHN7RWg4m9iZqNLSwOAlH4m0W2f5V8CqSI8/edit?usp=sharing
- wiki page -- https://www.lst1.iac.es/wiki/index.php/TON599 -- https://www.lst1.iac.es/wiki/index.php/3C454.3
