Signature of 3600-yr LaViolette flare in Antarctica 10Be spectra

10Be deposition rates from Vostok, Antarctica raw ice core records are periodic with 3592±57 yr at 99% significance, verified against the 10Be concentration raw data from both Vostok, as 3700±57 yr at 99%, and Taylor Dome, Antarctica, as 3800±61 yr at 99%. Also, Mg concentration data from Taylor Dom...

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Bibliographic Details
Main Author: Omerbashich, M.
Format: Report
Language:English
Published: 2021
Subjects:
Beryllium analysis
Vostok ice cores
cosmic rays
paleoclimate
Hallstadzeit cycle
LaViolette flares
High energy astrophysics
Gamma-ray bursts
Rapid bursts
Supernovae
Gamma-ray sources
Gamma-ray transient sources
Soft gamma-ray repeaters
Galactic center
Milky Way Galaxy physics
Magnetars
Milky Way magnetic fields
Sky surveys
Surface ices
Cosmochemistry
Cosmic abundances
Chemical abundances
Frozen-in elements
Time series analysis
Period search
Gauss-Vaniček spectral analysis
Milky Way
Taylor Dome
Antarc*
Antarctica
ice core
Online Access:https://zenodo.org/record/5228497
https://doi.org/10.5281/zenodo.5228497
Description
Summary:10Be deposition rates from Vostok, Antarctica raw ice core records are periodic with 3592±57 yr at 99% significance, verified against the 10Be concentration raw data from both Vostok, as 3700±57 yr at 99%, and Taylor Dome, Antarctica, as 3800±61 yr at 99%. Also, Mg concentration data from Taylor Dome cycle every 3965±16 yr at 99%. The Vostok data respond to the Hallstadzeit Solar cycle, as 2296±57 yr at 99%, perhaps its best estimate yet. After data separation at 2·105 atoms/cm2/yr (deposition rates) and 0.95·105 atoms/g of ice (concentrations) cutoffs, reflecting cosmic-ray background conditions at the Galactic boundary, only the discovered period remains and converges, as 3378±103 yr and 3346±85 yr, respectively; the Hallstadzeit cycle vanishes in both cases. Thus the observed ~3600-yr period is of extrasolar but galactic origin. Since 10Be periodicity is explainable only by rapid excesses in the atmospheric cosmic-ray influx, the discovered period is the signature of a regular burst occurrence from a galactic source. Based on 500-parsec Galactic Center (GC) GeV/TeV γ-ray surveys by the H.E.S.S. and INTEGRAL telescopes, the GC’s extremely active central region makes the best candidate-host for such bursts recently observed by ROSAT and Fermi satellites. I estimate the most recent epoch of 10Be maximum as 1085±57 CE, coinciding with the 1054–1056 CE historical account apparently of SN1054 (Crab supernova), and predict the next maximum 10Be in 4463±57 CE. Given continuous decadeslong exposure and the relatively short return period coinciding with known cataclysms, this recurrent LaViolette flare affects the Earth climate significantly.

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