Difference between revisions of "SN2024bch"

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(General Information)
(Spectral Energy Distribution)
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* ref_energy: 2TeV
 
* ref_energy: 2TeV
 
We use all good quality data
 
We use all good quality data
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 +
[[File:SN2024bch_sed_upper_limits.png | 1000 px]]
  
 
==== Light curves ====  
 
==== Light curves ====  

Revision as of 14:00, 19 June 2024

General Information

  • Name of the source: SN2024bch
  • Brief description of the source:
    • Object type: CCSN type IIn-L
    • Distance (Mpc): 16.56
    • Redshift: 0.00387
    • Host galaxy: NGC 3206
    • RA: 10:21:49.740 (hh mm ss), Dec: +56:55:40.51 (dd mm ss)
    • RA, Dec in deg (ICRS): 155.45725, +56.927919

People involved

Alphabetical order (corresponding authors)

  • Arnau Aguasca-Cabot
  • Alessandro Carosi
  • Alicia López-Oramas
  • Andrea Simongini (andrea.simongini@inaf.it)

Presentations

  • 2024-06-21 LST Galactic group Meeting:
  • 2024-06-10 LST Analysis Call: link to pdf
  • 2024-05-21 LST General Meeting, Prague: link to pdf

Data-taking Information

  • General information:
    • Start observation date: 2024-02-13
    • Total nights: 6
    • Total hours: 14.6
    • Total runs: 53
  • Observation condition: moon and dark
  • Observation mode: wobbles
  • Joint observations with MAGIC?: yes (16845-16863)
  • Joint analysis with MAGIC?: no


SN2024bch observations with LST-1
Run Number Night Run Start Time [UTC] Run Elapsed Time [min] Mean pointing zenith [deg] Wobble Position Used in stacked analysis Conditions ELOG
16771 20240213 00:29 20 32.6 W1 True dark 20240213
16772 20240213 00:49 19 30.5 W2 True dark 20240213
16773 20240213 01:08 24 29.9 W3 True dark 20240213
16774 20240213 01:32 17 28.1 W4 True dark 20240213
16775 20240213 01:49 20 xx W1 True dark 20240213
16776 20240213 02:09 20 xx W2 True dark 20240213
16777 20240213 02:29 20 28.9 W3 True dark 20240213
16778 20240213 02:49 20 xx W4 True dark 20240213
16779 20240213 03:09 22 30.3 W1 True dark 20240213
16780 20240213 03:31 19 32.5 W2 True dark 20240213
16781 20240213 03:50 17 34.3 W3 True dark 20240213
16803 20240214 01:11 26 29.3 W1 True dark 20240214
16804 20240214 01:37 18 28 W2 True dark 20240214
16805 20240214 01:55 15 28.5 W3 True dark 20240214
16806 20240214 02:10 20 27.8 W4 True dark 20240214
16807 20240214 02:30 23 28.5 W1 True dark 20240214
16808 20240214 02:53 18 30 W2 True dark 20240214
16809 20240214 03:11 20 31.4 W3 True dark 20240214
16810 20240214 03:31 21 32.3 W4 True dark 20240214
16811 20240214 03:52 4 34.4 W1 True dark 20240214
16815 20240215 00:14 16 33.3 W1 False dark 20240215
16816 20240215 00:30 20 31.4 W2 False dark 20240215
16817 20240215 00:50 21 30.5 W3 False dark 20240215
16818 20240215 01:11 21 28.7 W4 True dark 20240215
16819 20240215 01:32 18 28.3 W1 True dark 20240215
16820 20240215 01:50 20 28 W2 True dark 20240215
16821 20240215 02:10 22 28.6 W3 True dark 20240215
16822 20240215 02:32 19 28.5 W4 True dark 20240215
16823 20240215 02:51 19 29.7 W1 True dark 20240215
16824 20240215 03:10 22 31.9 W2 True dark 20240215
16825 20240215 03:32 18 33.4 W3 True dark 20240215
16826 20240215 03:50 12 34.6 W4 True dark 20240215
16845 20240216 01:02 21 29.4 W1 False dark 20240216
16846 20240216 01:23 20 28.3 W2 False dark 20240216
16847 20240216 01:43 22 28 W3 False dark 20240216
16848 20240216 02:05 19 27.8 W4 False dark 20240216
16849 20240216 02:24 21 28.6 W1 True dark 20240216
16850 20240216 02:45 20 29.9 W2 True dark 20240216
16851 20240216 03:05 21 31.4 W3 True dark 20240216
16852 20240216 03:26 20 32.5 W2 True dark 20240216
16853 20240216 03:46 14 34.5 W3 True dark 20240216
16863 20240218 03:10 19 32 W1 False moon 20240218
16864 20240218 03:29 18 34.7 W2 False moon 20240218
16866 20240218 03:47 19 36.1 W2 False moon 20240218
16867 20240218 04:06 28 38.1 W3 False moon 20240218
16868 20240218 04:25 3 xx xx False moon 20240218
16869 20240218 04:34 19 41.1 W4 True moon 20240218
16870 20240218 04:53 7 43.4 W1 True moon 20240218
16980 20240306 00:15 20 28 W1 True dark 20240306
16981 20240306 00:35 20 28 W2 True dark 20240306
16982 20240306 00:55 20 28.7 W3 True dark 20240306
16983 20240306 01:15 20 28.7 W4 True dark 20240306
16984 20240306 01:35 8 30 W1 True dark 20240306


Data quality cuts

We performed a standard source independent analysis for this source. The data quality is performed using the data_quality.ipynb notebook from the 2024-LST-School.

  • Source selection:
    • zenith_range = [0, 90]
    • min_angle_to_source = 0.35
    • max_angle_to_source = 0.45
  • Global cuts:
    • max_diffuse_nsb_std = 2.3
    • max_pointing_dec_std = 0.01
    • min_mean_fit_p = -3.
    • max_LS_periodogram_maxamplitude = 1e-2
    • min_drdi_index = -2.35
    • max_drdi_index = -2.1
    • min_drdi_at_422pe = 1.4
    • min_fraction_around_mode = 0.8
    • max_intensity_at_half_peak_rate = 70
  • Data quality plots:

Quality cuts.png

  • Relative light yield of the selected nights:

Light yield SN2024bch.png

  • Results:
    • Good quality runs: 41/53(77%)
    • Total time: 12.1 h
  • Extra notes:
    • 16868 is a very short run (3.4939323 min) due to data taking interruption by shifters
    • 16815 16816 16817 16847 16848 16867 were removed due to different NSB level

Data analysis

MC production

According to the data_quality.ipynb, the NSB level in the FoV of SN2024bch is low enough to consider the standard MC.

  • MC used:
    • 20240131_allsky_v0.10.5_all_dec_base
  • Declination line:
    • dec_6166 (4.8 deg away from SN 2024bch)

Declination map SN2024bch.png

Pointing issues

We could not fit 3 OFF positions in several runs due to small offset angular distance of the wobbles.

  • Possible solutions (applied in this analysis):
    • Reduce the max_theta_cut to 0.26 deg
    • Use only 1 OFF position

DL3 production

The DL3 are produced using the following standard parameters:

  • Intensity cut: [50GeV, infty]
  • w1: [0.01, 1]
  • r: [0, 1]
  • leakage_intensity_width_2: [0, 1]
  • event_type: [32, 32]
  • theta_containment: 0.7
  • gh_efficiency: 0.7
  • min_livetime: 300
  • max_zenith: 90

DL3 data are stored here:

  • /fefs/aswg/workspace/andrea.simongini/SN2024bch/DL3

Theta-squared plots

  • We produced theta-squared plots with all good quality data:
    • n_wobbles: 4
    • theta2_cut: 0.04
    • energy bounds: [50GeV-100GeV]; [100GeV-1TeV]; [1TeV-10TeV]
    • gammaness_cut: 0.7
    • theta2_cut: 0.07 deg2
  • Plots:

Theta2 plots SN2024bch.png

  • Results:
    • [50GeV-100GeV]: N_on = 287155; N_off = 6220812; Significance = -0.572341
    • [100GeV-1TeV]: N_on = 107335; N_off = 2284060; Significance = -1.255360
    • [1TeV-10TeV]: N_on = 267; N_off = 6189; Significance = -1.701900

No significant excess coming from this source! We go for upper-limits

High-level analysis

For the high-level analysis we set:

  • n_off_regions: 1
  • safe_mask_method: aeff-max (5%)
  • e_reco: [35GeV - 10TeV]
  • e_true: [1GeV - 50TeV]
  • n_reco_bin_p_dec: 3.5
  • n_true_bin_p_dec: 10

Note that the energy treshold (Eth) is ~30GeV. As discussed in the LST analysis call (see presentation from 2024-06-10) the safest and most conservative way to integrate fluxes is to set the lower energy bound of the reconstructed energy to 100GeV.


Spectral Energy Distribution

We are fitting our data with a simple power law distribution with the following parameters:

  • Gamma: -2.5
  • amplitude: 2e-12 cm−2s−1TeV−1
  • bounds: [1e-18, 1e-5] cm−2s−1TeV−1
  • ref_energy: 2TeV

We use all good quality data

SN2024bch sed upper limits.png

Light curves

Cross-check

Crab check

  • General information:
    • we applied the same data-quality cuts as SN2024bch
    • we used the same period of data taking (Feb-Mar 2024)
    • we applied the same max_theta_cut for IRF production
    • we employed a different Monte Carlo production
    • the DL3 and DL4 files are produced with the same specifications as SN2024bch
  • Data saved:
    • 29/33 runs (88%)
    • 8.5h
  • Relative light yield:

Light yield Crab SN2024bch.png


  • Monte Carlo production:
    • We used a different production with respect to SN2024bch
    • 20230927_v0.10.4_crab_tuned
    • dec_2276
  • Theta-squared plots:

Theta squared Crab SN2024bch.png

  • High-level analysis:

Progenitor analysis

Theoretical modeling

Optical analysis

Pre-explosion images