Russian Journal of Earth Sciences Russian Journal of Earth Sciences Russian Journal of Earth Sciences 1681-1208 46896 ОРИГИНАЛЬНЫЕ СТАТЬИ ORIGINAL ARTICLES ОРИГИНАЛЬНЫЕ СТАТЬИ Classification of solar X-ray flares on X-ray measurements on board geostationary satellites ``Elektro'' Classification of solar X-ray flares on X-ray measurements on board geostationary satellites ``Elektro'' Nusinov A A Nusinov A A Katyushina V V Katyushina V V Institute of Applied Geophysics, Moscow, Russia ru Institute of Applied Geophysics, Moscow, Russia ru Institute of Applied Geophysics, Moscow, Russia ru Institute of Applied Geophysics, Moscow, Russia ru 12 5 1 6 10 11 2021 https://rjes.ru/en/nauka/article/46896/view

Fluxes of soft X-ray radiation XR are the most important indicator of space weather. Currently, the standard is to classify the power of solar flares on the basis of XR measurements in 0.1#x2013;0.8#xA0;nm waverange onboard geostationary satellites GOES. As a part of the monitoring of conditions in the near-Earth space on Russian satellite of series "Elektro" a Geiger counter with an aluminum filter was used as the XR detector, the bandwidth of the detector is 0.05#x2013;0.4#xA0;nm. We propose a method of classification of solar flares and the calculation of the spectrum for the simulation of the ionosphere based on the satellite "Elektro" measurements. The method is based on the algorithm for calculating the flow of XR in the 0.1#x2013;0.8#xA0;nm based on the "Elektro" measurements data, and then use the model spectra of X-ray emission of the flare.

Fluxes of soft X-ray radiation XR are the most important indicator of space weather. Currently, the standard is to classify the power of solar flares on the basis of XR measurements in 0.1#x2013;0.8#xA0;nm waverange onboard geostationary satellites GOES. As a part of the monitoring of conditions in the near-Earth space on Russian satellite of series "Elektro" a Geiger counter with an aluminum filter was used as the XR detector, the bandwidth of the detector is 0.05#x2013;0.4#xA0;nm. We propose a method of classification of solar flares and the calculation of the spectrum for the simulation of the ionosphere based on the satellite "Elektro" measurements. The method is based on the algorithm for calculating the flow of XR in the 0.1#x2013;0.8#xA0;nm based on the "Elektro" measurements data, and then use the model spectra of X-ray emission of the flare.

Sun ionosphere X-rays flares modeling Sun ionosphere X-rays flares modeling

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