Monthly Notices of the Royal Astronomical Society, Volume 483,
Issue 4, March 2019, Pages 4578-4585 SNR G24.7+0.6 is a 9.5 kyrs radio and $\gamma$-ray supernova remnant evolving
in a dense medium. In ...the GeV regime, SNR G24.7+0.6
(3FHL\,J1834.1--0706e/FGES\,J1834.1--0706) shows a hard spectral index
($\Gamma$$\sim$2) up to $200$\,GeV, which makes it a good candidate to be
observed with Cherenkov telescopes such as MAGIC. We observed the field of view
of \snr\ with the MAGIC telescopes for a total of 31 hours. We detect very high
energy $\gamma$-ray emission from an extended source located 0.34\degr\ away
from the center of the radio SNR. The new source, named \mgc\ is detected up to
5\,TeV, and its spectrum is well-represented by a power-law function with
spectral index of $2.74 \pm 0.08$. The complexity of the region makes the
identification of the origin of the very-high energy emission difficult,
however the spectral agreement with the LAT source and overlapping position at
less than 1.5$\sigma$ point to a common origin. We analysed 8 years of
\fermi-LAT data to extend the spectrum of the source down to 60\,MeV.
\fermi-LAT and MAGIC spectra overlap within errors and the global broad band
spectrum is described by a power-law with exponential cutoff at
$1.9\pm0.5$\,TeV. The detected $\gamma$-ray emission can be interpreted as the
results of proton-proton interaction between the supernova and the CO-rich
surrounding.
Fast radio bursts (FRBs) are bright flashes observed typically at GHz frequencies with millisecond duration, whose origin is likely extragalactic. Their nature remains mysterious, motivating searches ...for counterparts at other wavelengths. FRB 121102 is so far the only source known to repeatedly emit FRBs and is associated with a host galaxy at redshift \(z \simeq 0.193\). We conducted simultaneous observations of FRB 121102 with the Arecibo and MAGIC telescopes during several epochs in 2016--2017. This allowed searches for millisecond-timescale burst emission in very-high-energy (VHE) gamma rays as well as the optical band. While a total of five FRBs were detected during these observations, no VHE emission was detected, neither of a persistent nature nor burst-like associated with the FRBs. The average integral flux upper limits above 100 GeV at 95% confidence level are \(6.6 \times 10^{-12}~\mathrm{photons\ cm^{-2}\ s^{-1}}\) (corresponding to luminosity \(L_{\rm VHE} \lesssim 10^{45}~\mathrm{erg\ s^{-1}}\)) over the entire observation period, and \(1.2 \times 10^{-7}~ \mathrm{photons\ cm^{-2}\ s^{-1}}\) (\(L_{\rm VHE} \lesssim 10^{49}~\mathrm{erg\ s^{-1}}\)) over the total duration of the five FRBs. We constrain the optical U-band flux to be below 8.6 mJy at 5-\(\sigma\) level for 1-ms intervals around the FRB arrival times. A bright burst with U-band flux \(29~\mathrm{mJy}\) and duration \(\sim 12\) ms was detected 4.3 s before the arrival of one FRB. However, the probability of spuriously detecting such a signal within the sampled time space is 1.5% (2.2 \(\sigma\), post-trial), i.e. consistent with the expected background. We discuss the implications of the obtained upper limits for constraining FRB models.
PKS 1510-089 is a flat spectrum radio quasar strongly variable in the optical and GeV range. We search for low-state VHE gamma-ray emission from PKS 1510-089. We aim to characterize and model the ...source in a broad-band context, which would provide a baseline over which high states and flares could be better understood. We use daily binned Fermi-LAT flux measurements of PKS 1510-089 to characterize the GeV emission and select the observation periods of MAGIC during low state of activity. For the selected times we compute the average radio, IR, optical, UV, X-ray and gamma-ray emission to construct a low-state spectral energy distribution of the source. The broadband emission is modelled within an External Compton scenario with a stationary emission region through which plasma and magnetic field are flowing. We perform also the emission-model-independent calculations of the maximum absorption in the broad line region (BLR) using two different models. Results. The MAGIC telescopes collected 75 hrs of data during times when the Fermi-LAT flux measured above 1 GeV was below 3x10-8cm-2s-1, which is the threshold adopted for the definition of a low gamma-ray activity state. The data show a strongly significant (9.5{\sigma}) VHE gamma-ray emission at the level of (4.27+-0.61stat)x10-12cm-2s-1 above 150GeV, a factor 80 smaller than the highest flare observed so far from this object. Despite the lower flux, the spectral shape is consistent with earlier detections in the VHE band. The broad-band emission is compatible with the EC scenario assuming a large emission region located beyond the BLR. For the first time the gamma-ray data allow us to place a limit on the location of the emission region during a low gamma-ray state of a FSRQ. For the used model of the BLR, the 95% C.L. on the location of the emission region allows us to place it at the distance >74% of the outer radius of the BLR.
Clusters of galaxies are the largest known gravitationally bound structures in the Universe, with masses around \(10^{15}\ M_\odot\), most of it in the form of dark matter. The ground-based Imaging ...Atmospheric Cherenkov Telescope MAGIC made a deep survey of the Perseus cluster of galaxies using almost 400 h of data recorded between 2009 and 2017. This is the deepest observational campaign so far on a cluster of galaxies in the very high energy range. We search for gamma-ray signals from dark matter particles in the mass range between 200 GeV and 200 TeV decaying into standard model pairs. We apply an analysis optimized for the spectral and morphological features expected from dark matter decays and find no evidence of decaying dark matter. From this, we conclude that dark matter particles have a decay lifetime longer than \(\sim10^{26}\)~s in all considered channels. Our results improve previous lower limits found by MAGIC and represent the strongest limits on decaying dark matter particles from ground-based gamma-ray instruments.
A neutrino with energy of \(\sim\)290 TeV, IceCube-170922A, was detected in coincidence with the BL Lac object TXS~0506+056 during enhanced gamma-ray activity, with chance coincidence being rejected ...at \(\sim 3\sigma\) level. We monitored the object in the very-high-energy (VHE) band with the MAGIC telescopes for \(\sim\)41 hours from 1.3 to 40.4 days after the neutrino detection. Day-timescale variability is clearly resolved. We interpret the quasi-simultaneous neutrino and broadband electromagnetic observations with a novel one-zone lepto-hadronic model, based on interactions of electrons and protons co-accelerated in the jet with external photons originating from a slow-moving plasma sheath surrounding the faster jet spine. We can reproduce the multiwavelength spectra of TXS 0506+056 with neutrino rate and energy compatible with IceCube-170922A, and with plausible values for the jet power of \(\sim 10^{45} - 4 \times 10^{46} {\rm erg \ s^{-1}}\). The steep spectrum observed by MAGIC is concordant with internal \(\gamma\gamma\) absorption above a few tens of GeV entailed by photohadronic production of a \(\sim\)290 TeV neutrino, corroborating a genuine connection between the multi-messenger signals. In contrast to previous predictions of predominantly hadronic emission from neutrino sources, the gamma-rays can be mostly ascribed to inverse Compton up-scattering of external photons by accelerated electrons. The X-ray and VHE bands provide crucial constraints on the emission from both accelerated electrons and protons. We infer that the maximum energy of protons in the jet co-moving frame can be in the range \(\sim 10^{14}\) to \(10^{18}\) eV.
The MAGIC telescopes observed S2 0109+22 in 2015 July during its flaring activity in high energy gamma rays observed by Fermi-LAT. We analyse the MAGIC data to characterise the very high energy (VHE) ...gamma-ray emission of S2 0109+22, which belongs to the subclass of intermediate synchrotron peak (ISP) BL Lac objects. We study the multi-frequency emission in order to investigate the source classification. Finally, we compare the source long-term behaviour to other VHE gamma-ray emitting (TeV) blazars. We performed a temporal and spectral analysis of the data centred around the MAGIC interval of observation (MJD 57225-57231). Long-term radio and optical data have also been investigated using the discrete correlation function. The redshift of the source is estimated through optical host-galaxy imaging and also using the amount of VHE gamma-ray absorption. The quasi-simultaneous multi-frequency spectral energy distribution (SED) is modelled with the conventional one-zone synchrotron self-Compton (SSC) model. MAGIC observations resulted in the detection of the source at a significance level of \(5.3\,\sigma\). The VHE gamma-ray emission of S2 0109+22 is variable on a daily time scale. VHE gamma-ray luminosity of the source is lower than the average of TeV BL Lacs. The optical polarization, and long-term optical/radio behaviour of the source are different from the general population of TeV blazars. All these findings agree with the classification of the source as an ISP BL Lac object. We estimate the source redshift as \(z = 0.36 \pm 0.07\). The SSC parameters describing the SED are rather typical for blazars.
We report on the detection of flaring activity from the Fanaroff-Riley I radio galaxy NGC 1275 in very-high-energy (VHE, E \(>\) 100 GeV) gamma rays with the MAGIC telescopes. Observations were ...performed between 2016 September and 2017 February as part of a monitoring program. The brightest outburst with \(\sim1.5\) times the Crab Nebula flux above 100 GeV (C.U.) was observed during the night between 2016 December 31 and 2017 January 1 (fifty times higher than the mean previously measured in two observational campaigns between 2009 and 2011). Significant variability of the day-by-day light curve was measured, the shortest flux-doubling time-scales was found to be of \((611\pm101)\) min. The combined spectrum of the MAGIC data during the strongest flare state and simultaneous data from the Fermi-LAT around 2017 January 1 follows a power-law with an exponential cutoff at the energy \((492\pm35)\) GeV. Simultaneous optical flux density measurements in the R-band obtained with the KVA telescope are also presented and the correlation between the optical and gamma-ray emission is investigated. Due to possible internal pair-production, the fast flux variability constrains the Doppler factor to values which are inconsistent with a large viewing angle as observed in the radio band. We investigate different scenarios for the explanation of fast gamma-ray variability, namely emission from: magnetospheric gaps, relativistic blobs propagating in the jet (mini-jets) or external cloud (or star) entering the jet. We find that the only plausible model to account for the luminosities here observed would be the production of gamma rays in a magnetospheric gap around the central black hole only in the eventuality of an enhancement of the magnetic field threading the hole from its equipartition value with the gas pressure in the accretion flow.
A search for tau neutrino induced showers with the MAGIC telescopes is presented. The MAGIC telescopes located at an altitude of 2200 m a.s.l. in the Canary Island of La Palma, can point towards the ...horizon or a few degrees below across an azimuthal range of about 80 degrees. This provides a possibility to search for air showers induced by tau leptons arising from interactions of tau neutrinos in the Earth crust or the surrounding ocean. In this paper we show how such air showers can be discriminated from the background of very inclined hadronic showers by using Monte Carlo simulations. Taking into account the orography of the site, the point source acceptance and the event rates expected have been calculated for a sample of generic neutrino fluxes from photo-hadronic interactions in AGNs. The analysis of about 30 hours of data taken towards the sealeads to a 90\% C.L. point source limit for tau neutrinos in the energy range from \(1.0 \times 10^{15}\) eV to \(3.0 \times 10^{18}\) eV of about \(E_{\nu_{\tau}}^{2}\times \phi (E_{\nu_{\tau}}) < 2.0 \times 10^{-4}\) GeV cm\(^{-2}\) s\(^{-1}\) for an assumed power-law neutrino spectrum with spectral index \(\gamma\)=-2. However, with 300 hours and in case of an optimistic neutrino flare model, limits of the level down to \(E_{\nu_{\tau}}^{2}\times \phi (E_{\nu_{\tau}}) < 8.4 \times 10^{-6}\) GeV cm\(^{-2}\) s\(^{-1}\) can be expected.
The dwarf spheroidal galaxy Ursa Major II (UMaII) is believed to be one of the most dark-matter dominated systems among the Milky Way satellites and represents a suitable target for indirect dark ...matter (DM) searches. The MAGIC telescopes carried out a deep observation campaign on UMaII between 2014 and 2016, collecting almost one hundred hours of good-quality data. This campaign enlarges the pool of DM targets observed at very high energy (E\(\gtrsim\)50GeV) in search for signatures of dark matter annihilation in the wide mass range between \(\sim\)100 GeV and \(\sim\)100 TeV. To this end, the data are analyzed with the full likelihood analysis, a method based on the exploitation of the spectral information of the recorded events for an optimal sensitivity to the explored dark matter models. We obtain constraints on the annihilation cross-section for different channels that are among the most robust and stringent achieved so far at the TeV mass scale from observations of dwarf satellite galaxies.
MAGIC (Major Atmospheric Gamma Imaging Cherenkov) is a system of two 17 m diameter, F/1.03 Imaging Atmospheric Cherenkov Telescopes (IACT). They are dedicated to the observation of gamma rays from ...galactic and extragalactic sources in the very high energy range (VHE, 30 GeV to 100 TeV). This submission contains links to the proceedings for the 35th International Cosmic Ray Conference (ICRC2017), held in Bexco, Busan, Korea from the 12th to the 17th of July, 2017.