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A. K. Pavlov, A. V. Blinov, A. N. Konstantinov, V. M. Ostryakov, G. I. Vasilyev, M. A. Vdovina, P. A. Volkov, AD 775 pulse of cosmogenic radionuclides production as imprint of a Galactic gamma-ray burst, Monthly Notices of the Royal Astronomical Society, Volume 435, Issue 4, 11 November 2013, Pages 2878–2884, https://doi.org/10.1093/mnras/stt1468
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Abstract
We suggest an explanation of a sharp increase in the abundance of cosmogenic radiocarbon found in tree rings dated AD 775. The increase could originate from high-energy irradiation of the atmosphere by a Galactic gamma-ray burst. We argue that, unlike a cosmic ray event, a gamma-ray burst does not necessarily result in a substantial increase in long-lived 10Be atmospheric production. At the same time, the 36Cl nuclide would be generated in the amounts detectable in the corresponding ice-core samples from Greenland and Antarctica. These peculiar features allow experimental discrimination of nuclide effects caused by gamma-ray bursts and by powerful proton events.
1 INTRODUCTION
Gamma-ray bursts (GRBs) are among the brightest events in the Universe. Nowadays the orbital Fermi mission detects about one GRB per day (Gehrels & Meszaros 2012). All GRBs discovered by direct measurements are of extragalactic origin so far. However, present models of hypernovae and/or merging of two compact objects such as neutron stars (NSs) and black holes (BHs) in binary systems imply the possibility that such events could occur in the Galaxy as well. High energy emission from a Galactic GRB would produce considerable quantities of long-lived cosmogenic radionuclides in the Earth atmosphere.
Studies of astrophysical phenomena by means of radionuclide measurements in natural archives have already been carried out for more than 50 years. Their production in the atmosphere is mainly a result of nuclear interactions caused by cosmic rays (CRs). The correlation of 14C abundance in tree rings with CR intensity, solar activity and geomagnetic field strength on a long time-scale is well understood (Lal & Peters 1967). However, the 14C abundance response to such impulsive events as powerful solar flares, gamma-rays from supernova (SN) explosions and GRBs has not been reliably established until recently.
Miyake et al. (2012) presented determination of 14C content in two Japanese cedar tree-ring sequences which showed a sharp increase in samples dated AD 774–775. These results were later confirmed by two independent measurements (in Germany and Switzerland) in tree rings of German oak corresponding to the same time span (Usoskin et al. 2013). This indicates a global character of the increase. Impulsive GRBs and proton events were considered as possible reasons of such a 14C spike (Eichler & Mordecai 2012; Hambaryan & Neuhäuser 2013; Pavlov et al. 2013; Usoskin et al. 2013). In the present paper, we extend the critical analysis of possible astrophysical sources of the 14C increase and make predictions of their traces in 10Be and 36Cl concentrations in polar ice. We consider an impact from a Galactic GRB as a possible cause of the observed 14C spike in AD 774–775. This idea was previously considered by Hambaryan & Neuhäuser (2013) but their estimations of 10Be and 14C production rate in the atmosphere were roughly approximative, and their conclusions were based on the overestimation of the 14C pulse production rate of Miyake et al. (2012; see below).
In our model secondary particle cascades are generated in the atmosphere due to photonuclear reactions of primary gamma-rays with atmospheric atoms. Subsequent production of radionuclides by these secondary particles is much more efficient than their direct production in the photonuclear reactions at observed GRB energies. Finally, we calculate altitude dependence of nuclide production rate in the stratosphere (QS) and troposphere (QT). Transition from the sharp increase in QS(14C) and QT(14C) to its atmospheric concentration change requires an adequate modelling of the global carbon cycle. Here we use the reservoir model of radiocarbon cycle able to account for the short (1–2 years) increase in 14C signal. The model was previously used to reconstruct CR intensity from the 14C tree-ring measurements on the millennial time-scale (Kocharov et al. 1983). A cosmic gamma-ray-induced rise of the 14C atmospheric production would be accompanied by changes in generation of other long-lived cosmogenic nuclides. We estimate possible variations of 10Be and 36Cl concentration in polar ice and make predictions of their detection.
2 SIMULATION OF 14C, 10Be and 36Cl PRODUCTION IN THE ATMOSPHERE
Simulations of cosmogenic nuclides production in the atmosphere due to high-energy interactions with cosmic gamma-rays were performed with a specifically suited code based on the latest version of the geant4.9.6.p02 (physics list QGSP_BIC_HP). The library contains a regularly updated data base of nuclear cross-sections in a wide energy range. The developed code exploits the Monte Carlo approach and thus allows tracing all the secondary particles produced in nuclear interactions. This code was used in our previous studies of atmospheric ionization processes (Vasilyev, Ostryakov & Pavlov 2008; Pavlov et al. 2012). Production rates of 14C, 10Be and 36Cl were calculated for a 130-km deep atmosphere with 1-km resolution and averaged over the spherical layer because the horizontal mixing is much faster than the vertical one. The incident gamma-ray flux was considered to be plane-parallel.
Photonuclear reactions of high-energy gamma-rays (Eγ > 10 MeV) result in the atmospheric production of secondary nuclear-active particles and it is neutrons that are most important for our analysis. Our simulations indicate that the main channel for 14C production is the reaction of secondary neutrons with nitrogen, 14N(n,p)14C, similar to the case of incident primary protons. The yield function for 14C nucleus production by gamma-rays (the number of 14C nuclei produced by a single photon of given energy) is shown in Fig. 1. The maximum of the yield function at Eγ ∼ 23 MeV corresponds to the giant dipole resonance for nitrogen and oxygen nuclei. For energies higher than 70 MeV, the gradual growth of the yield function is due to the total increase in number of secondary particles. Gamma-rays with Eγ > 10 MeV also produce 36Cl. Production of 10Be begins from energies higher than Eγ ∼ 30 MeV. Both isotopes are produced in reactions with secondary neutrons as well. However, the significant generation of 10Be takes place only at photon energies Eγ > 50 MeV and goes via several channels. These are the direct photodisintegration nuclear reactions and spallation reactions by secondary neutrons (at En > 15 MeV) on nitrogen and oxygen nuclei.
The presented yield function (Fig. 1) has slightly increased compared to the previous result of Pavlov et al. (2013) because of the improved photonuclear reaction model and renewed data base of neutron reactions cross-sections. Correspondingly, the calculated atmospheric 14C production rate has increased by 20–30 per cent for the same initial parameters.
The average global production rate of 14C by CRs in the atmosphere is estimated as ∼1.6–2 atoms cm−2 s−1 (Beer, McCracken & von Steiger 2012; Kovaltsov, Mishev & Usoskin 2012), and it is 0.02–0.04 and ∼1.1×10−3 atoms cm−2 s−1 for 10Be and 36Cl, respectively (Blinov et al. 2000; Kovaltsov & Usoskin 2010; Beer et al. 2012). Partition of the production rate between the stratosphere and the troposphere (QS/QT) depends on the geographical latitude, incident particle type and its energy. This ratio is a function of the local tropopause altitude which is higher in the tropical regions (16–18 km) compared to polar caps (7–10 km). For the mean CR energy spectra averaged over the 11-year solar cycle QS/(QS + QT) ratio is 65 per cent (Masarik & Beer 2009). About the same proportions are valid for the other considered nuclides. Production by CR particles is also affected by the geomagnetic field screening of the low-energy part of the spectra. It should be noted that there is no geomagnetic cut-off for gamma-rays.
3 NUCLIDE PRODUCTION RATES AND CONCENTRATIONS IN TERRESTRIAL ARCHIVES
Abundance of 14C in tree rings directly reflects its tropospheric concentration. Concentration of 10Be and 36Cl in Antarctic and Greenland ice-core samples depends on their tropospheric sedimentation rate and on the ice accumulation rate. Mean tropospheric residence time for the nuclides generated in the stratosphere is about 1.5–3.0 years (Blinov et al. 2000; Heikkila, Beer & Feichter 2009). Therefore, any stratospheric variations of QS would be transmitted to the troposphere with amplitude attenuation and time lag. Air exchange between stratosphere and troposphere is a complicated seasonal process occurring more efficiently at mid-latitudes. There are atmospheric processes leading to the increase in the height of the tropopause and to its ‘break-through’. These effects result in sudden injections of the stratospheric air to the troposphere and, hence, to the 14C, 10Be and 36Cl tropospheric concentration increase even for constant QS and QT rates.
The 10Be produced in the stratosphere is attached to aerosols and precipitates to the Earth within ∼1.5 years predominantly at mid-latitudes. 10Be of tropospheric origin is deposited on the surface almost at the very site of its production. Therefore, natural 10Be transport is significantly simpler than that of 14C though it still contains some uncertainty because of the complicated troposphere–stratosphere interaction. Correctness of the interpretation of 10Be ice-core measurements strongly depends on the sample dating which, in turn, relies on the ice accumulation rate data. As a rule, the ice horizon dating is based on the local glaciological models and employs peculiar time markers (known volcano eruptions, variations in 18O/16O ratios, etc.) for independent check. The atmospheric flux of 10Be and 36Cl is calculated as the product of their abundance in the sample and its ice accumulation rate. The relationship between nuclide atmospheric flux and its production rate is more complicated because of the latitude dependence of the fall-out.
4 POSSIBLE REASONS OF THE ABRUPT INCREASE OF 14C ABUNDANCE IN AD 775
There are not so many astrophysical phenomena that could result in a short-duration increase of the CR flux or in high-energy gamma-ray emission sufficient to explain the annual variation in the Δ14C measured in AD 775 tree rings. These are a powerful solar proton event with an anomalously high flux of energetic particles, a nearby GRB and gamma-ray emission from a nearby ordinary SN explosion. The latter scenario may be excluded since neither a remnant of such an explosion has been detected nor a historical evidence of such an event is present (Miyake et al. 2012).
Solar flares as a probable source of the Δ14C increase imply an extra-high energy release up to ∼1035 erg in solar energetic particles (SEPs), which is 103 times higher than any of the historically observed flares on the Sun (Usoskin & Kovaltsov 2012; Usoskin et al. 2013). Though such powerful flares were actually observed on other Sun-like stars (Maehara et al. 2012), such an event of solar origin would have resulted in the intense aurora observable even at low latitudes on the Earth. Up to our knowledge there is no historical evidence of an appropriate episode. In addition, such a powerful flare (or several flares within one year) could have resulted in high production of 10Be and 36Cl nuclides (Konstantinov et al. 1992a,b) which has not been detected so far.
GRBs are the most powerful sources of gamma-ray emission with energy release up to ∼9 × 1054 erg in a single event for isotropic emission (e.g. GRB 080916C; see Gehrels & Meszaros 2012). GRB models also imply that the emission could be collimated within several degrees, which requires 10–100 times lower energy of the source. Then, their occurrence frequency should be increased in order to explain their observations at the Earth orbit. Observed GRBs clearly form two distinct classes – short (<2 s, SGRBs) and long (>2 s, LGRBs). The long bursts are connected to the explosions of super massive stars (hypernovae) producing BHs and relativistic jets (Nakar 2007). However, the same problem as for the close SN arises, namely, the absence of an observable remnant of such an explosion. SGRBs are not connected to SN explosions; they are rather explained as merging of two compact objects producing a BH: two NSs, BH and NS. In this case no remnant of an explosion is expected. Maximum of the measured isotropic-equivalent energy release for such events was about 1053 erg (GRB 090510; Ackermann et al. 2010). Several thousands of extragalactic GRBs have been registered up to now. The Fermi observatory detects ∼300 events annually, and 20 per cent of them are the SGRBs (Gehrels & Meszaros 2012). The estimate of the GRB frequency in our Galaxy depends on several factors, such as the GRB radiation model (isotropic or anisotropic), the abundance of binary compact objects and the population of massive stars. Recent estimates of GRB frequency in the Galaxy range from one event per 4 × 105 yr for isotropic emission model to one event per 5 × 103 yr for the model with beaming factor in the range of 1–100 (Kalogera et al. 2004; Nakar & Gal-Yam 2006; Nakar 2007; Coward et al. 2012; Dominik et al. 2012).
According to our calculations, the mean yield of 14C equals to 20–55 atoms erg−1 for the gamma-ray flux entering the atmosphere from a GRB with typical spectral parameters of Band function. Yields of 10Be and 36Cl are 0.05–0.07 and 0.025–0.035 atoms erg−1, respectively. Only rarely observed power-law spectrum events with specific parameters of GRBs could have produced needed 14C pulse. The calculations for such specific event (GRB 971218) are presented in Table 1.
α . | β . | E0 (MeV) . | Fluence in the upper atmosphere . | Distance (R) for different energies . | ||
---|---|---|---|---|---|---|
. | . | . | (106 erg cm−2) . | of a GRB (isotropic model) (kpc) . | ||
. | . | . | . | (1050 erg) . | (1053 erg) . | (1055 erg) . |
−0.05 | −2.10 | 1.5 | 4.5 | 0.47 | 14.9 | 149 |
−0.05 | −2.10 | 5.0 | 3.8 | 0.52 | 16.3 | 163 |
−1.10 | −2.10 | 1.5 | 5.5 | 0.43 | 13.5 | 135 |
−1.10 | −2.10 | 2.8 | 5.0 | 0.45 | 14.1 | 141 |
0.00 | −2.10 | 1.5 | 4.5 | 0.49 | 14.9 | 149 |
0.00 | −2.10 | 2.8 | 4.1 | 0.49 | 15.7 | 157 |
1.00 | −2.10 | 1.5 | 4.1 | 0.49 | 15.6 | 156 |
1.00 | −2.10 | 2.8 | 3.7 | 0.52 | 16.4 | 164 |
−1.08a | −2.49 | 0.7 | 11 | 0.30 | 9.50 | 95 |
−0.90b | − | 12 | 1.8 | 0.74 | 23.4 | 234 |
α . | β . | E0 (MeV) . | Fluence in the upper atmosphere . | Distance (R) for different energies . | ||
---|---|---|---|---|---|---|
. | . | . | (106 erg cm−2) . | of a GRB (isotropic model) (kpc) . | ||
. | . | . | . | (1050 erg) . | (1053 erg) . | (1055 erg) . |
−0.05 | −2.10 | 1.5 | 4.5 | 0.47 | 14.9 | 149 |
−0.05 | −2.10 | 5.0 | 3.8 | 0.52 | 16.3 | 163 |
−1.10 | −2.10 | 1.5 | 5.5 | 0.43 | 13.5 | 135 |
−1.10 | −2.10 | 2.8 | 5.0 | 0.45 | 14.1 | 141 |
0.00 | −2.10 | 1.5 | 4.5 | 0.49 | 14.9 | 149 |
0.00 | −2.10 | 2.8 | 4.1 | 0.49 | 15.7 | 157 |
1.00 | −2.10 | 1.5 | 4.1 | 0.49 | 15.6 | 156 |
1.00 | −2.10 | 2.8 | 3.7 | 0.52 | 16.4 | 164 |
−1.08a | −2.49 | 0.7 | 11 | 0.30 | 9.50 | 95 |
−0.90b | − | 12 | 1.8 | 0.74 | 23.4 | 234 |
α . | β . | E0 (MeV) . | Fluence in the upper atmosphere . | Distance (R) for different energies . | ||
---|---|---|---|---|---|---|
. | . | . | (106 erg cm−2) . | of a GRB (isotropic model) (kpc) . | ||
. | . | . | . | (1050 erg) . | (1053 erg) . | (1055 erg) . |
−0.05 | −2.10 | 1.5 | 4.5 | 0.47 | 14.9 | 149 |
−0.05 | −2.10 | 5.0 | 3.8 | 0.52 | 16.3 | 163 |
−1.10 | −2.10 | 1.5 | 5.5 | 0.43 | 13.5 | 135 |
−1.10 | −2.10 | 2.8 | 5.0 | 0.45 | 14.1 | 141 |
0.00 | −2.10 | 1.5 | 4.5 | 0.49 | 14.9 | 149 |
0.00 | −2.10 | 2.8 | 4.1 | 0.49 | 15.7 | 157 |
1.00 | −2.10 | 1.5 | 4.1 | 0.49 | 15.6 | 156 |
1.00 | −2.10 | 2.8 | 3.7 | 0.52 | 16.4 | 164 |
−1.08a | −2.49 | 0.7 | 11 | 0.30 | 9.50 | 95 |
−0.90b | − | 12 | 1.8 | 0.74 | 23.4 | 234 |
α . | β . | E0 (MeV) . | Fluence in the upper atmosphere . | Distance (R) for different energies . | ||
---|---|---|---|---|---|---|
. | . | . | (106 erg cm−2) . | of a GRB (isotropic model) (kpc) . | ||
. | . | . | . | (1050 erg) . | (1053 erg) . | (1055 erg) . |
−0.05 | −2.10 | 1.5 | 4.5 | 0.47 | 14.9 | 149 |
−0.05 | −2.10 | 5.0 | 3.8 | 0.52 | 16.3 | 163 |
−1.10 | −2.10 | 1.5 | 5.5 | 0.43 | 13.5 | 135 |
−1.10 | −2.10 | 2.8 | 5.0 | 0.45 | 14.1 | 141 |
0.00 | −2.10 | 1.5 | 4.5 | 0.49 | 14.9 | 149 |
0.00 | −2.10 | 2.8 | 4.1 | 0.49 | 15.7 | 157 |
1.00 | −2.10 | 1.5 | 4.1 | 0.49 | 15.6 | 156 |
1.00 | −2.10 | 2.8 | 3.7 | 0.52 | 16.4 | 164 |
−1.08a | −2.49 | 0.7 | 11 | 0.30 | 9.50 | 95 |
−0.90b | − | 12 | 1.8 | 0.74 | 23.4 | 234 |
Table 1 shows the combinations of GRB spectral parameters, distances and isotropic-equivalent energy outputs which could provide the observed Δ14C signal. It comes out that a required GRB-like source of hard emission should be located in our Galaxy or in satellite galaxies such as the Magellanic Clouds.
It is worth mentioning that for the source distances beyond ∼10 kpc there is a considerable probability of a galactic hypernovae (a possible source of a LGRB) being screened by dense interstellar gas-dust clouds. It allows considering it together with the SGRBs as a possible source of the AD 775 event.
There is a unique galactic SN remnant W49B with coordinates G43.3−0.2 (i.e. close to the celestial equator) at the distance of 8–11 kpc with the age ∼1000 years (Abdo et al. 2010). Analysis of Chandra X-ray observational data (Keohane et al. 2007; Lopez et al. 2011; Lopez et al. 2013) demonstrated that W49B was probably produced by a bipolar/jet-driven core collapse. X-ray observations did not confirm a presence of an NS in W49B and the authors assumed production of a BH by the SN explosion. SN progenitor mass is estimated to be about 25 solar masses for an aspherical SN explosion model. Such a combination of parameters is close to a hypernova event that could produce a LGRB with a necessary γ-ray pulse in 775 AD. Table 2 gives the range of possible LGRB parameters for such an event. Note that the required γ-ray fluence weakly depends on specific GRB parameters combination (±20 per cent).
α . | β . | E0 . | Fluence in the upper atmosphere . | Isotropic-equivalent energy of . | Isotropic-equivalent energy of . |
---|---|---|---|---|---|
. | . | (MeV) . | (106 erg cm−2) . | a GRB at 8 kpc (1052 erg) . | a GRB at 11 kpc (1052 erg) . |
−0.05 | −2.1 | 1.5 | 4.5 | 2.9 | 5.5 |
−0.05 | −2.1 | 5.0 | 3.8 | 2.4 | 4.6 |
−1.1 | −2.1 | 1.5 | 5.5 | 3.5 | 6.6 |
−1.1 | −2.1 | 2.8 | 5.0 | 3.2 | 6.1 |
0 | −2.1 | 1.5 | 4.5 | 2.9 | 5.4 |
0 | −2.1 | 2.8 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 1.5 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 2.8 | 3.7 | 2.4 | 4.5 |
α . | β . | E0 . | Fluence in the upper atmosphere . | Isotropic-equivalent energy of . | Isotropic-equivalent energy of . |
---|---|---|---|---|---|
. | . | (MeV) . | (106 erg cm−2) . | a GRB at 8 kpc (1052 erg) . | a GRB at 11 kpc (1052 erg) . |
−0.05 | −2.1 | 1.5 | 4.5 | 2.9 | 5.5 |
−0.05 | −2.1 | 5.0 | 3.8 | 2.4 | 4.6 |
−1.1 | −2.1 | 1.5 | 5.5 | 3.5 | 6.6 |
−1.1 | −2.1 | 2.8 | 5.0 | 3.2 | 6.1 |
0 | −2.1 | 1.5 | 4.5 | 2.9 | 5.4 |
0 | −2.1 | 2.8 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 1.5 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 2.8 | 3.7 | 2.4 | 4.5 |
α . | β . | E0 . | Fluence in the upper atmosphere . | Isotropic-equivalent energy of . | Isotropic-equivalent energy of . |
---|---|---|---|---|---|
. | . | (MeV) . | (106 erg cm−2) . | a GRB at 8 kpc (1052 erg) . | a GRB at 11 kpc (1052 erg) . |
−0.05 | −2.1 | 1.5 | 4.5 | 2.9 | 5.5 |
−0.05 | −2.1 | 5.0 | 3.8 | 2.4 | 4.6 |
−1.1 | −2.1 | 1.5 | 5.5 | 3.5 | 6.6 |
−1.1 | −2.1 | 2.8 | 5.0 | 3.2 | 6.1 |
0 | −2.1 | 1.5 | 4.5 | 2.9 | 5.4 |
0 | −2.1 | 2.8 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 1.5 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 2.8 | 3.7 | 2.4 | 4.5 |
α . | β . | E0 . | Fluence in the upper atmosphere . | Isotropic-equivalent energy of . | Isotropic-equivalent energy of . |
---|---|---|---|---|---|
. | . | (MeV) . | (106 erg cm−2) . | a GRB at 8 kpc (1052 erg) . | a GRB at 11 kpc (1052 erg) . |
−0.05 | −2.1 | 1.5 | 4.5 | 2.9 | 5.5 |
−0.05 | −2.1 | 5.0 | 3.8 | 2.4 | 4.6 |
−1.1 | −2.1 | 1.5 | 5.5 | 3.5 | 6.6 |
−1.1 | −2.1 | 2.8 | 5.0 | 3.2 | 6.1 |
0 | −2.1 | 1.5 | 4.5 | 2.9 | 5.4 |
0 | −2.1 | 2.8 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 1.5 | 4.1 | 2.6 | 4.9 |
1 | −2.1 | 2.8 | 3.7 | 2.4 | 4.5 |
Fig. 2 shows the modelled evolution of radiocarbon atmospheric abundance, Δ14C(t), for the pulse increase of its production rate (stratospheric and tropospheric) caused by a GRB along with the experimental data. The total amount of the produced radiocarbon is 1.7×108 atoms cm−2 that is a factor of 3–4 less (Pavlov et al. 2013) than the estimate of Miyake et al. (2012).
A similar result was obtained by Usoskin et al. (2013). As discussed above, the shape of the Δ14C(t) curve mainly depends on the exchange parameters τij. In our simulations we used the following initial steady-state parameters: τST = 3 yr, τTS = 18.8 yr, τBT = 68.8 yr, τTB = 23 yr, τMT = 28.7 yr, τTM = 11 yr, τMD = 53.1 yr and τDM = 2000 yr. After the pulse injection of 14C τST varies within time period of 10 years (the values are presented in Figs 2 and 3). The most important of them is the stratosphere–troposphere exchange time, τST, that determines the Δ14C(t) rising front steepness. Figs 2 and 3 demonstrate that the three-year value used by Miyake et al. (2012) does not explain the observed sharp rise of 14C tropospheric concentration (Pavlov et al. 2013). A faster exchange rate of τST ∼ 1.0–2.0 years is required for the best fit. Note that temporary decrease of τST could be a consequence of the GRB impact on the atmospheric ozone abundance (see below). Effects of such an impact can persist in the atmosphere for the following 5–10 years (Thomas et al. 2005).
5 PECULIARITIES IN 10Be AND 36Cl RECORDS FROM THE GRB EVENT
Our calculations show that gamma-rays with energies 10–100 MeV do not produce a measurable excess of 10Be in the atmosphere (the yields of 10Be and 36Cl are 0.05–0.07 and 0.025–0.035 atoms erg−1, respectively). It is because the gamma-rays produce photonuclear reactions on atmospheric nitrogen and oxygen with secondary neutrons output in the energy range below the 10Be spallation threshold, n ∼ 15–20 MeV. This conclusion differs from the results of Hambaryan & Neuhäuser (2013) who erroneously considered the energy spectrum of secondary neutrons for 10Be production as identical to the primary gamma-ray spectrum. It resulted in the tenfold overestimate of the 10Be production.
The considerable production of 36Cl, in contrast to the negligible 10Be production, turns out to be a peculiar feature of a GRB impact (its ‘isotopic footprint’). CRs mainly produce 36Cl in spallation reactions on 40Ar with approximately the same threshold as for 10Be production on nitrogen and oxygen. Thus, the mean 36Cl atmospheric production rate appears to be about 20 times less than that for 10Be. However, there is another channel of 36Cl atmospheric production, namely the 36Ar(n,p)36Cl reaction. For CRs this channel gives about 10 per cent of the total yield determined by the argon isotopic ratio40Ar/36Ar = 300. The threshold of the latter reaction is close to ∼0.5 MeV and neutrons with energy ∼ 1 MeV generated by gamma-rays in photonuclear reactions will efficiently produce 36Cl without any concomitant 10Be production. Then, the corresponding pulse of 36Cl production could reach a detectable level without measurable 10Be pulse.
In contrast to GRB emission, any proton event like a solar super energetic flare (or sequence of flares) would cause the simultaneous increase of 14C and 10Be production. The corresponding 10Be concentration amplitude in an ice-core record would be much more prominent (by orders of magnitude) than the atmospheric Δ14C peak since there is no ‘dilution’ effect for 10Be nuclide. Also, the CR-induced 10Be production always significantly exceeds the 36Cl one.
Besides the nuclide generation, GRB radiation must obviously produce strong ionization of the upper atmosphere which, by means of ion-molecular reactions, would yield large amounts of nitric oxides (NOx) in the stratosphere. In turn, NOx are a well-known catalyst of ozone depletion. The stratospheric ozone is responsible for the temperature inversion above the tropopause. Its concentration decline caused by Galactic GRB emission may reach 30 per cent at the equator and up to 70 per cent in the polar regions (Thomas et al. 2005). It is important to note that a 20–30 per cent decrease would last for several years. Ozone depletion causes temperature decrease in the lower stratosphere. Thus, the tropopause could rise up and it could become more ‘transparent’ due to the increased sensitivity to tropospheric disturbances (cyclones, anticyclones, etc.). Such a scenario would further lead to accelerated stratosphere–troposphere exchange, stratospheric air injections and finally to additional input of 14C and 10Be to the troposphere. Thus, the tropospheric concentration of 14C would increase with higher rate compared to the ‘stationary’ exchange rate. Basically, a sharp spike of nitrate concentration in polar ice could indicate such event provided that the high-resolution ice-core data are available and the clear protocol connecting local nitrate concentration in ice to its stratospheric production is developed (Wolff et al. 2008).
Studies of Antarctic ice at Dome Fuji station showed about 30 per cent increase of 10Be concentration in samples dated presumably AD 755–785 (Horiuchi et al. 2008). However, the complexity of ice dating procedure and poor temporal resolution (about 10 years) does not allow a reliable connection of this record with the discussed 14C peak. Any other detailed Antarctic ice-core data are absent for this time interval. On the other hand, the data from Greenland ice-cores do not show any distinguished peak around AD 775. For ordinary atmospheric transport character, 10Be stratospheric input is negligibly small to central Antarctic regions (Beer et al. 2012), whereas in Greenland the stratospheric10Be falls down along with the tropospheric one. Whenever the height of the polar tropopause changes and/or the local air transport is abruptly disturbed, the local nuclide deposition rate could show a sharp rise even for constant production rate conditions in Antarctic region. The 1–2 km tropospheric height increase is sufficient to produce the 10Be signal in the Antarctic ice that would be equivalent to the 30–50 per cent increase of tropospheric production rate. In this case the signal in 10Be would be different in Greenland and Antarctic. Namely, the relative changes of deposition rate would be weaker in Greenland compared to the Central Antarctica where the fall-out mainly contains 10Be of tropospheric origin. Asymmetry in 10Be signal is a result of the asymmetry in the global atmospheric processes and it is not caused by the Northern (or Southern) origin of GRB with respect to the Earth's poles.
The hypothesis of a GRB origin of the AD 775 Δ14C peak meets some difficulty in the absence of historic evidence of associated unusual atmospheric phenomena. Short-term intense ionization of the atmosphere could lead to visible recombination airglow. However, it is quite probable that a Galactic GRB occurred in the Southern hemisphere (which contains most of the Galactic plane) or airglow flash could be localized outside Europe and Asia regions, where a written evidence of the event is hardly possible to be found.
6 CONCLUSIONS
A galactic GRB may be considered as a plausible explanation of the experimentally discovered annual pulse increase in the 14C atmospheric abundance corresponding to AD 775. Irradiation of the atmosphere by the flux of high-energy gamma-rays could become the source of the measured increase.
Typical energy spectra and fluxes of gamma-rays from such a Galactic source could peculiarly generate a significant amount of 14C without production of noticeable excess of 10Be and this fact makes a clear distinction between gamma-ray events and CR-induced ones. On the other hand, along with 14C gamma-rays can produce a relatively large amount of atmospheric 36Cl which could become, once detected in some natural archives, a reliable specific indication of a galactic GRB.
Galactic SN remnant W49B is likely to be associated with the LGRB event which could have caused Δ14C peak in 775 AD.
The impact of nearby GRB on the upper atmosphere could produce a strong depletion of the ozone layer, a lift of the tropopause and an increase of its transparency. This could result in the additional input of stratospheric 10Be to the Central Antarctic, and therefore, in formation of a 10Be concentration peak in Antarctic ice-core records even without an increase of the global atmospheric production rate. The discussed local effect would be much less pronounced in Greenland. Therefore, one of its identification marks would be the asymmetry of Greenland and Antarctic ice-core signals.
The research was partly supported by the Programme 22 of basic research of the Presidium of RAS ‘Fundamental problems in the studies and development of the Solar system’.