Spectra of the Thunderstorm Correlated Electron and Gamma-Ray Measured at Aragats

1. Spectra of the Thunderstorm Correlated Electron and Gamma-Ray Measured at Aragats BagratMailyan and Ashot Chilingarian

2. Particle acceleration in atmospheric electric fieldsRunaway Relativistic Electron Avalanche (RREA) TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

3. Detectors of Aragats Space-Environmental Center Detectors located outdoor and indoor correspond to the various energy thresholds of measured particles. Indoor detectors also located under roof materials with different thicknesses. These detectors, sensitive to various energies, allow us to construct the energy spectrum of the additional particles. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

4. Recently 3 layers of 1 cm and 1layer of 3cm scintillating detectors are installed outdoors. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

5. Aragats Solar Neutron Telescope (ASNT) ASNT detects not only particle count rate, but also energy releases spectra in scintillators! TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

6. Light attenuation in thick scintillators Chilingarian et al., 2007 TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

7. Reconstruction of the energy spectra of incidentgammas The unfolding of the gamma ray spectrum above the roof of the MAKET building at altitude of 3250 m was made in the following way: • A power spectrum with initial parameters randomly chosen from predetermined interval is generated; • This spectrum is used to simulate traversal of gamma rays via roof and ASNT detector components to finally obtain simulated energy release spectrum; • The obtained simulated spectrum is compared with experimental one; the discrepancy (quality function) and initial spectrum parameters are stored; • If number of iterations is not fulfilled go to step 1. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

8. Reconstruction of the gamma spectrum of September 19, 2009 event The minimum of quality function corresponds to power index -2.96. Electron contamination of gamma spectrum is taken into account. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

9. Electron contamination of gamma spectra and gamma contamination of electron spectra TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

10. Construction of electron spectra of September 19, 2009 We correct the electron energy spectrum for the gamma-ray contamination. After the electron number correction for gamma contamination, 59472, 28268, 22036and10982 electrons were estimated to be detected by MAKET outdoor, MAKET indoor and SEVAN detectors respectively. According to calculations and simulations 4 types of detectors have energies approximately equal to 9, 12, 15, 18 MeV. Errors about 2 MeV, reflecting uncertainties in determination of the energy thresholds, are taken due to the complicated structure of roof substance To compare electron and gamma spectra, gamma differential spectrum was integrated. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

11. Electron and gamma ray spectra of September 19, 2009 event TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

12. Reconstruction of the electron spectrum just below the thundercloud electric field We can assume that maximal energy of the RREA electrons can reach 40-50 MeV. (Marisaldi et al., 2010) Taking into account the maximal energy of detected electrons and assuming that electrons lose 200 keV per meter of air, thundercloud altitude was estimated to be ~100-150 m!By trying different trial spectra, evaluating the avalanche from 3380 till 3250 m and comparing each obtained spectrum with experimental one we have found the RREA spectrum, just below the thundercloud. The exponential index was found to be ~ -0.152. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

13. Reconstruction of the electron spectrum just below the thundercloud electric field TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

14. Parameters of the fit for September 19 event TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

15. Electron and gamma spectra of September 19, 2009 event TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

16. Comparison with other events • We have perform the same operations as for September 19 event to reconstruct the gamma spectra and obtain electron spectra of three smaller thunderstorm events. • Gamma contamination of electron spectra are taken into account. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

17. May 21 event: More gammas than electrons TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

18. July 9 event: No electrons only gammas TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

19. August 26, 2010 event The energy thresholds were estimated to be 1.5, 4.5 and 7.5 MeV for upper, middle and lower detectors respectively. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

20. Comparison of the differential gamma spectra of the three events TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

21. Comparison with gamma spectra calculated and measured with other groups • According to simulations by J.R.Dwyer (2008), the RREA spectrum is independent on thundercloud electric field. The mean electron energy is ~7.3 MeV. • Using Baksan data, Lidvansky and Khaerdinov (2009) assume 1000 , 2000, 3000 m cloud height, to obtain 3 different values of the power spectra index from to -2.57 to -4.36, for various events discussed in the paper. For instance, at October 11, 2003 the spectral indexes were estimated to be -3.78, -4.09, -4.36 for 1000, 2000, 3000 m respectively. • Tsuchiya et al., (2009) have simultaneously observed electrons and gammas spectrum extending up to 10 MeV on the top of the mountain Norikura, 2700 m above sea level. The RREA electrons source distance is estimated to be ~90m and spectral index of the gamma spectrum is -1.15 0.09; no energy spectrum of electrons was presented. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

22. Conclusion For the first time we present the energy spectra of RREA electrons and gamma rays, using the variety of ASEC detectors including the enhanced possibilities of ASNT to measure energy releases in the thick scintillator. Gamma ray spectra are described by power law and electron spectra by exponential law. The intensities of additional particle fluxes for the discussed events are different. Electron/gamma ratio also varies for different thunderstorm events. There is an event without electron detections >9 MeV. Probably this is connected with thundercloud height. TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia

23. Acknowledgements The work was partially supported by the grant No. CRDF-NFSAT-SCS MES RA ECSP-69/A-27 Thank you for attention! TEPA - 2010, September 6 - 11, 2010, Nor Amberd, Armenia