Abstracts of Interest
Selected by:
Peter Marinos
Abstract: 2306.11026
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Title:On the "Hysteresis Effects" observed by AMS02 in Cosmic Ray Solar Modulations
Download PDFAbstract: The AMS02 collaboration has recently published high precision daily measurements of the spectra of cosmic ray protons, helium nuclei and electrons taken during a time interval of approximately 10 years from 2011 to 2020. Positron spectra averaged over distinct 27 days intervals have also been made public. The AMS02 collaboration has shown some intriguing "hysteresis" effects observed comparing the fluxes of protons and helium nuclei or protons and electrons. In this work we address the question of the origin of these effects. We find that the spectral distortions generated by propagation in the heliosphere are significantly different for particles with electric charge of opposite sign (an effect already well established), with different behaviour before and after the solar magnetic field polarity reversal at solar maximum. This results in hysteresis effects for the p/e comparison that follow the 22-year solar cycle. On the other hand particles with electric charge of the same sign suffer modulations that are approximately equal. The hysteresis effects observed for a helium/proton comparison can then be understood as the consequence of the fact that the two particles have interstellar spectra of different shape, and the approximately equal spectral distortions generated by propagation in the heliosphere have a rigidity dependence that is a function of time. These hysteresis effects can in fact be observed studying the time dependence of the shape of the spectra of a single particle type, and also generate short time loop-like structures in the hysteresis curves correlated with large solar activity events such as CME's. A description of solar modulations that includes these effects must go beyond the simple Force Field Approximation (FFA) model. A minimal, two-parameter generalization of the FFA model that gives a good description of the observations is presented.
Abstract: 2306.11276
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Title:The spin axes of globular clusters and correlations with gamma-ray emission
Download PDFAbstract: A growing number of Milky Way globular clusters have been identified to possess a noticeable degree of solid-body rotation. For several clusters, the combination of stellar proper motions and radial velocities allows for 3-dimensional spin axes to be extracted. In this paper we consider the orientations of these spin axes, and ask whether they are correlated with any other properties of the clusters -- either global properties to do with their orbits and origin, or internal properties related to the cluster composition. We discuss the possibility of alignments between the spin axes of globular clusters, chemodynamical groupings, and their orbital poles. We also point out a previously unidentified negative correlation between the measured gamma-ray emissivities and the inclination of the globular cluster spins with respect to the line of sight. Given that this correlation is not present in other wavelengths, we cannot conclusively attribute it solely to sampling bias. If the correlation holds up to scrutiny with more data, it may be indicative of sources of anisotropic gamma-ray emission in globular clusters. We discuss the plausibility of such an anisotropy arising from a population of dynamically formed millisecond pulsars with some degree of spin-orbit alignment.
Abstract: 2306.11579
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Title:The detection of possible $γ$-ray quasi-periodic modulation with $\sim$600 days from the blazar S2 0109+22
Download PDFAbstract: In this work, we analyzed the long term gamma-ray data by a Fermi Large Area Telescope (Fermi-LAT) of blazar S2 0109+22, ranging from 2008 to 2023. The quasi-periodic oscillations (QPOs) of blazars aided in investigating the physical properties of internal supermassive black holes, the nature of variability, and the underlying radiation mechanism. We employed four different methods--Weighted Wavelet Z-transform, Lomb-Scargle periodogram, REDFIT and phase folded light curve analysis, for searching QPO signals. Our analysis identified a possible QPO behavior with a periodicity of $\sim$600 days in November 2013 to January 2023 at a significance level of 3.5 $\sigma$. This QPO signal sustained $\sim$9 years, corresponding to 5.6 cycles, which was in good agreement with the previously observed of periodicity $\sim$657 days in radio. We explained this phenomenon based on the accretion model and the lighthouse effect, in a binary black hole system.
Abstract: 2306.12134
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Title:4FGL J1844.4-0306: high-energy emission likely from the supernova remnant G29.37+0.1
Download PDFAbstract: Very-high-energy (VHE) observations have revealed approximately 100 TeV sources in our Galaxy, and a significant fraction of them are under investigation for understanding their origin. We report our study of one of them, HESS~J1844$-$030. It is found possibly associated with the supernova remnant (SNR) candidate G29.37+0.1, and detailed studies of the source region at radio and X-ray frequencies have suggested that this SNR is a composite one, containing a pulsar wind nebula (PWN) powered by a candidate young pulsar. As the GeV source 4FGL~J1844.4$-$0306 is also located in the region with high positional coincidence, we analyze its $\gamma$-ray data obtained with the Large Area Telescope on-board the {\it Fermi Gamma-ray Space Telescope }. We determine the GeV $\gamma$-ray emission is extended, described with a Log-Parabola function. The obtained spectrum can be connected to that of the VHE source HESS J1844$-$030. Given the properties and those from multi-frequency studies, we discuss the origin of the $\gamma$-ray emission by considering that the two \gr\ sources are associated. Our modeling indicates that while the TeV part would have either a hadronic (from the SNR) or a leptonic origin (from the putative PWN), the GeV part would arise from a hadronic process. Thus we conclude that 4FGL~J1844.4$-$0306 is the likely GeV counterpart to G29.37+0.1.
Abstract: 2306.12326
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Title:What is the nature of the HESS J1731-347 compact object?
Download PDFAbstract: Once further confirmed in future analyses, the radius and mass measurement of HESS J1731-347 with $M=0.77^{+0.20}_{-0.17}~M_{\odot}$ and $R=10.4^{+0.86}_{-0.78}~\rm km$ will be among the lightest and smallest compact object ever detected. This raises many questions about its nature and opens up the window for different theories to explain such a measurement. In this article, we use the information from Doroshenko et al. (2022) on the mass, radius, and surface temperature together with the multi-messenger observations of neutron stars to investigate the possibility that HESS J1731-347 is one of the lightest observed neutron star (NS), a strange star (SS), a hybrid star (HS) with an early deconfinement phase transition, or a dark matter (DM) admixed neutron star. The nucleonic and quark matter are modeled within realistic equation of states (EoSs) with a self-consistent calculation of the pairing gaps in quark matter. By performing the joint analysis of the thermal evolution and mass-radius constraint, we find evidence that within a 1$\sigma$ confidence level, HESS J1731-347 is consistent with the neutron star scenario with the soft EoS as well as with a strange and hybrid star with the early deconfinement phase transition with a strong quark pairing and neutron star admixed with dark matter.
Abstract: 2306.12715
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Title:Possible contribution of X-ray binary jets to the Galactic cosmic ray and neutrino flux
Download PDFAbstract: For over a century, the identification of high-energy cosmic ray (CR) sources remains an open question. For Galactic CRs with energy up to $10^{15}$ eV, supernova remnants (SNRs) have traditionally been thought the main candidate source. However, recent TeV gamma-ray observations have questioned the SNR paradigm. Propagating CRs are deflected by the Galactic magnetic field, hence, gamma-rays and neutrinos produced via inelastic hadronic interactions are the only means for unveiling the CR sources. In this work, we study the gamma-ray and neutrino emission produced by CRs accelerated inside Galactic jets of stellar-mass black holes in X-ray binaries (BHXBs). We calculate the intrinsic neutrino emission of two prototypical BHXBs, Cygnus X-1 and GX 339-4, for which we have high-quality, quasi-simultaneous multiwavelength spectra. Based on these prototypical sources, we discuss the likelihood of the 35 known Galactic BHXBs to be efficient CR accelerators. Moreover, we estimate the potential contribution to the CR spectrum of a viable population of BHXBs that reside in the Galactic plane. When these BHXBs go into outburst, they may accelerate particles up to 100s of TeV that contribute to the diffuse gamma-ray and neutrino spectra while propagating in the Galactic medium. Using HERMES, an open-source code that calculates the hadronic processes along the line of sight, we discuss the contribution of BHXBs to the diffuse gamma-ray and neutrino fluxes, and compare these to their intrinsic gamma-ray and neutrino emissions. Finally, we discuss the contribution of BHXBs to the observed spectrum of Galactic CRs.
Abstract: 2306.12840
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Title:Constraints on the cosmological parameters with three-parameter correlation of Gamma-ray bursts
Download PDFAbstract: As one of the most energetic and brightest events, gamma-ray bursts (GRBs) can be treated as a promising probe of the high-redshift universe. Similar to type Ia supernovae (SNe Ia), GRBs with same physical origin could be treated as standard candles. We select GRB samples with the same physical origin, which are divided into two groups. One group is consisted of 31 GRBs with a plateau phase feature of a constant luminosity followed by a decay index of about -2 in the X-ray afterglow light curves, and the other has 50 GRBs with a shallow decay phase in the optical light curves. For the selected GRB samples, we confirm that there is a tight correlation between the plateau luminosity $L_0$, the end time of plateau $t_b$ and the isotropic energy release $E_{\gamma,iso}$. We also find that the $L_0-t_b-E_{\gamma,iso}$ correlation is insensitive to the cosmological parameters and no valid limitations on the cosmological parameters can be obtained using this correlation. We explore a new three-parameter correlation $L_0$, $t_b$, and the spectral peak energy in the rest frame $E_{p,i}$ ($L_0-t_b-E_{p,i}$), and find that this correlation can be used as a standard candle to constrain the cosmological parameters. By employing the optical sample only, we find the constraints of $\Omega_m = 0.697_{-0.278}^{+0.402}(1\sigma)$ for a flat $\Lambda$CDM model. For the non-flat $\Lambda$CDM model, the best-fitting results are $\Omega_m = 0.713_{-0.278}^{+0.346}$, $\Omega_{\Lambda} = 0.981_{-0.580}^{+0.379}(1\sigma)$. For the combination of the X-ray and optical smaples, we find $\Omega_m = 0.313_{-0.125}^{+0.179}(1\sigma)$ for a flat $\Lambda$CDM model, and $\Omega_m = 0.344_{-0.112}^{+0.176}$, $\Omega_{\Lambda} = 0.770_{-0.416}^{+0.366}(1\sigma)$ for a non-flat $\Lambda$CDM model.
Abstract: 2306.12960
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Title:Observations of the Crab Nebula and Pulsar with the Large-Sized Telescope Prototype of the Cherenkov Telescope Array
Download PDFAbstract: CTA (Cherenkov Telescope Array) is the next generation ground-based observatory for gamma-ray astronomy at very-high energies. The Large-Sized Telescope prototype (\LST{}) is located at the Northern site of CTA, on the Canary Island of La Palma. LSTs are designed to provide optimal performance in the lowest part of the energy range covered by CTA, down to $\simeq 20$ GeV. \LST{} started performing astronomical observations in November 2019, during its commissioning phase, and it has been taking data since then. We present the first \LST{} observations of the Crab Nebula, the standard candle of very-high energy gamma-ray astronomy, and use them, together with simulations, to assess the basic performance parameters of the telescope. The data sample consists of around 36 hours of observations at low zenith angles collected between November 2020 and March 2022. \LST{} has reached the expected performance during its commissioning period - only a minor adjustment of the preexisting simulations was needed to match the telescope behavior. The energy threshold at trigger level is estimated to be around 20 GeV, rising to $\simeq 30$ GeV after data analysis. Performance parameters depend strongly on energy, and on the strength of the gamma-ray selection cuts in the analysis: angular resolution ranges from 0.12 to 0.40 degrees, and energy resolution from 15 to 50\%. Flux sensitivity is around 1.1\% of the Crab Nebula flux above 250 GeV for a 50-h observation (12\% for 30 minutes). The spectral energy distribution (in the 0.03 - 30 TeV range) and the light curve obtained for the Crab Nebula agree with previous measurements, considering statistical and systematic uncertainties. A clear periodic signal is also detected from the pulsar at the center of the Nebula.
Abstract: 2306.13135
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Title:CMB Spectral Distortions from an Axion-Dark Photon-Photon Interaction
Download PDFAbstract: The presence of a plethora of light spin 0 and spin 1 fields is motivated in a number of BSM scenarios, such as the axiverse. The study of the interactions of such light bosonic fields with the Standard Model has focused mostly on interactions involving only one such field, such as the axion ($\phi$) coupling to photons, $\phi F \tilde F$, or the kinetic mixing between photon and the dark photon, $ F F_D$. In this work, we continue the exploration of interactions involving two light BSM fields and the standard model, focusing on the mixed axion-photon-dark-photon interaction $\phi F \tilde F_D$. If either the axion or dark photon are dark matter, we show that this interaction leads to conversion of the CMB photons into a dark sector particle, leading to a distortion in the CMB spectrum. We present the details of these unique distortion signatures and the resulting constraints on the $\phi F \tilde F_D$ coupling. In particular, we find that for a wide range of masses, the constraints from these effect are stronger than on the more widely studied axion-photon coupling.
Abstract: 2306.13246
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Title:Studying the mass sensitivity of air-shower observables using simulated cosmic rays
Download PDFAbstract: Using CORSIKA simulations, we investigate the mass sensitivity of cosmic-ray air-shower observables for sites at the South Pole and Malargüe, Argentina, the respective locations of the IceCube Neutrino Observatory and the Pierre Auger Observatory. Exact knowledge of observables from air-shower simulations was used to study the event-by-event mass separation between proton, helium, oxygen, and iron primary cosmic rays with a Fisher linear discriminant analysis. Dependencies on the observation site as well as the energy and zenith angle of the primary particle were studied in the ranges from $10^{16.0}-10^{18.5}\,$eV and $0^\circ$ to $60^\circ$: they are mostly weak and do not change the qualitative results. Promising proton-iron mass separation is achieved using combined knowledge of all studied observables, also when typical reconstruction uncertainties are accounted for. However, even with exact measurements, event-by-event separation of intermediate-mass nuclei is challenging and better methods than the Fisher discriminant and/or the inclusion of additional observables will be needed. As an individual observable, high-energy muons ($> 500\,$GeV) provide the best event-by-event mass discrimination, but the combination of muons of any energy and $X_{\text{max}}$ provides already a high event-by-event separation between proton-iron primaries at both sites. We also confirm that the asymmetry and width parameters of the air-shower longitudinal profile, $R$ and $L$, are mass sensitive. Only $R$ seems to be suitable for event-by-event mass separation, but $L$ can potentially be used to statistically determine the proton-helium ratio. Overall, our results motivate the coincident measurement of several air-shower observables, including at least $X_{\text{max}}$ and the sizes of the muonic and electromagnetic shower components, for the next generation of air-shower experiments.
Abstract: 2306.14100
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Title:Unusual integrated metallicity profile of our Milky Way
Download PDFAbstract: The heavy element abundance profiles in galaxies place stringent constraint on galaxy growth and assembly history. Low-redshift galaxies generally have a negative metallicity gradient in their gas and stars. Such gradients are thought to be a natural manifestation of galaxy inside-out formation. As the Milky Way is currently the only spiral galaxy in which we can measure temporally-resolved chemical abundances, it enables unique insights into the origin of metallicity gradients and their correlation with the growth history of galaxies. However, until now, these unique abundance profiles had not been translated into the integrated-light measurements needed to seamlessly compare with the general galaxy population. Here we report the first measurement of the light-weighted, integrated stellar metallicity profile of our Galaxy. We find that the integrated metallicity profile of the Milky Way has a '$\wedge$'-shape broken metallicity profile, with a mildly positive gradient inside a Galactocentric radius of 7 kpc and a steep negative gradient outside. This metallicity profile appears unusual when compared to Milky Way-mass star-forming galaxies observed in the MaNGA survey and simulated in the TNG50 cosmological simulation. The analysis of the TNG50 simulated galaxies suggests that the Milky Way's positive inner gradient may be due to an inside-out quenching process. The steep negative gradient in the outer disc, however, is challenging to explain in the simulations. Our results suggest the Milky Way may not be a typical spiral galaxy for its mass regarding metallicity distribution and thus offers insight into the variety of galaxy enrichment processes.
Abstract: 2306.14261
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Title:Kinetic simulations and gamma-ray signatures of Klein-Nishina relativistic magnetic reconnection
Download PDFAbstract: Black hole and neutron star environments often comprise collisionless plasmas immersed in strong magnetic fields and intense baths of low-frequency radiation. In such conditions, relativistic magnetic reconnection can tap the magnetic field energy, accelerating high-energy particles that rapidly cool by inverse Compton (IC) scattering the dense photon background. At the highest particle energies reached in bright gamma-ray sources, IC scattering can stray into the Klein-Nishina regime. Here, the Comptonized photons exceed pair-production threshold with the radiation background and may thus return their energy to the reconnecting plasma as fresh electron-positron pairs. To reliably characterize observable signatures of such Klein-Nishina reconnection, in this work, we present first-principles particle-in-cell simulations of pair-plasma relativistic reconnection coupled to Klein-Nishina and pair-production physics. The simulations show substantial differences between the observable signatures of Klein-Nishina reconnection and reconnection coupled only to low-energy Thomson IC cooling (without pair production). The latter regime exhibits strong harder-when-brighter behaviour; the former involves a stable spectral shape independent of overall brightness. This spectral stability is reminiscent of flat-spectrum radio quasar (FSRQ) GeV high states, furnishing evidence that Klein-Nishina radiative physics operates in FSRQs. The simulated Klein-Nishina reconnection pair yield spans from low to order-unity and follows an exponential scaling law in a single governing parameter. Pushing this parameter beyond its range studied here might give way to a copious pair-creation regime. Besides FSRQs, we discuss potential applications to accreting black hole X-ray binaries, the M87$^*$ magnetosphere, and gamma-ray binaries.
Abstract: 2306.14354
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Title:The Swift Deep Galactic Plane Survey (DGPS) Phase-I Catalog
Download PDFAbstract: The \textit{Swift} Deep Galactic Plane Survey is a \textit{Swift} Key Project consisting of 380 tiled pointings covering 40 deg$^{2}$ of the Galactic Plane between longitude $10$\,$<$\,$|l|$\,$<$\,$30$ deg and latitude $|b|$\,$<$\,$0.5$ deg. Each pointing has a $5$ ks exposure, yielding a total of 1.9 Ms spread across the entire survey footprint. Phase-I observations were carried out between March 2017 and May 2021. The Survey is complete to depth $L_X$\,$>$\,$10^{34}$ erg s$^{-1}$ to the edge of the Galaxy. The main Survey goal is to produce a rich sample of new X-ray sources and transients, while also covering a broad discovery space. Here, we introduce the Survey strategy and present a catalog of sources detected during Phase-I observations. In total, we identify 928 X-ray sources, of which 348 are unique to our X-ray catalog. We report on the characteristics of sources in our catalog and highlight sources newly classified and published by the DGPS team.
Abstract: 2306.14359
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Title:Interacting Supernova Remnants: a population model for the Cherenkov Telescope Array
Download PDFAbstract: The work presented in this thesis is focused on the interacting supernova remnants (iSNRs), a class of gamma-ray emitting SNR where the radiation arise from the interaction of the SNR with a massive molecular cloud. At the moment only 16 iSNR are known. Before this work, there was not any population study of these sources. Here is proposed a model for the Galactic population of iSNRs which can be used in order to predict the number of these systems in the Galaxy and how many of these will be detectable by the next generation of {\gamma}-ray instruments. iSNRs are of particular interest for the particle acceleration study because these objects have been proved to be sites of acceleration of protons up to high energies. Furthermore, high-energy $\gamma$-ray emission can pinpoint the presence of energetic leptons or ions and help to constraint the acceleration efficiency and maximum energy of accelerated particles The model presented her was only achievable through the creation of a complete catalog of {\gamma}-ray (both GeV and TeV) supernova remnants that for each supernova remnants gives collect the physical and spectral information available in litterature. Simulating and analyzing the synthetic population, it was found that the Cherenkov Telescope Array (CTA) will be able to duplicate the number of detected interacting systems in its survey of the Galactic plane.
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