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Register a new userDistinct High Energy Cutoff Variation Patterns in Two Seyfert Galaxies
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Investigating how the cutoff energy $E_{rm cut}$ varies with X-ray flux and photon index $Gamma$ in individual AGNs opens a new window to probe the yet unclear coronal physics. So far $E_{rm cut}$ variations have only been detected in several AGNs but different patterns have been reported. Here we report new detections of $E_{rm cut}$ variations in two Seyfert galaxies with multiple NuSTAR exposures. While in NGC 3227 $E_{rm cut}$ monotonically increases with $Gamma$, the $E_{rm cut}$-$Gamma$ relation exhibits a $Lambda$ shape in SWIFT J2127.4+5654 ($E_{rm cut}$ increasing with $Gamma$ at $Gamma$ $lesssim$ 2.05, but reversely decreasing at $Gamma$ $gtrsim$ 2.05), indicating more than a single underlying mechanism is involved. Meanwhile both galaxies show softer spectra while they brighten in X-ray, a common phenomenon in Seyfert galaxies. Plotting all 7 AGNs with $E_{rm cut}$ variations ever reported with NuSTAR observations in the $E_{rm cut}$-$Gamma$ diagram, we find they could be unified with the $Lambda$ pattern. Although the sample is small and SWIFT J2127.4+5654 is the only source with $Gamma$ varying across the break point thus the only one exhibiting the complete $Lambda$ pattern in a single source, the discoveries shed new light on the coronal physics in AGNs. Possible underlying physical mechanisms are discussed.
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Narrow-line Seyfert 1 galaxies (NLSy1s) are a well-established class of $gamma$-ray sources, showing the presence of a jet like the more common flat-spectrum radio quasars. The evidence of $gamma$-ray emission poses the issue of the location of the $gamma$-ray emitting zone and of the contribution of the $gamma$-$gamma$ absorption within the broad-line region (BLR), since such objects have been detected by Fermi-LAT in the MeV-GeV energy range but not by imaging atmospheric Cherenkov telescopes beyond 100 GeV. We discuss how the spectral properties of three NLSy1s (SBS 0846+513, PMN J0948+0022, and PKS 1502+036) derived from the Fermi Large Area Telescope Fourth Source Catalog (4FGL) compare with theoretical models based on the observed properties of the BLR. In particular, we focus on the question on how simple power-law spectral models and log-parabolic ones could be disentangled in $gamma$-ray narrow-line Seyfert 1 galaxies by means of current Fermi-LAT or future imaging atmospheric Cherenkov telescopes data. We find that the only possibility for a log-parabolic model to mimic a power-law model in the energy band above $E sim 100$ GeV is to have a very small value of the curvature parameter $ beta sim 0.05$.
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