Hostname: page-component-848d4c4894-r5zm4 Total loading time: 0 Render date: 2024-06-26T19:16:05.937Z Has data issue: false hasContentIssue false
  • English
  • Français

Radiocarbon Production by the Gamma-Ray Component of Supernova Explosions

Published online by Cambridge University Press:  18 July 2016

Paul E. Damon ,
Dai Kaimei ,
Grant E. Kocharov ,
Irina B. Mikheeva  and
Alexei N. Peristykh
Paul E. Damon
Affiliation:
NSF-Arizona Accelerator Facility for Radioisotope Analysis, Department of Geosciences, The University of Arizona, Tucson, Arizona 85721 USA
Dai Kaimei
Affiliation:
NSF-Arizona Accelerator Facility for Radioisotope Analysis, Department of Geosciences, The University of Arizona, Tucson, Arizona 85721 USA Department of Physics, Nanjing University, Nanjing 210008 China
Grant E. Kocharov
Affiliation:
A. F. Ioffe Physical-Technical Institute, St. Petersburg 194021 Russia Solar-Terrestrial Environment Laboratory, Nagoya University, Nagoya, Japan
Irina B. Mikheeva
Affiliation:
NSF-Arizona Accelerator Facility for Radioisotope Analysis, Department of Geosciences, The University of Arizona, Tucson, Arizona 85721 USA A. F. Ioffe Physical-Technical Institute, St. Petersburg 194021 Russia
Alexei N. Peristykh
Affiliation:
NSF-Arizona Accelerator Facility for Radioisotope Analysis, Department of Geosciences, The University of Arizona, Tucson, Arizona 85721 USA A. F. Ioffe Physical-Technical Institute, St. Petersburg 194021 Russia
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

We selected SN1006, the brightest and closest to Earth of all supernovas historically observed, for a study of 14C production by e,e+-bremsstrahlung cascades initiated by hard γ rays (>10 MeV) from that event. During the cascade, bremsstrahlung energies eventually fall within a giant (n,γ), (n,2γ) cross-section, peaking at 23 MeV and approaching effectively zero below 10 MeV and above 40 MeV. The neutrons are absorbed primarily in the reaction 14N(n,p)14C. Cellulose from single-year tree rings from ad 1003 to ad 1020 was measured to determine ∆14C. Three years after the first visual observation of SN1006, ∆14C rose and remained above pre-ad 1009 values until ad 1018. Comparison of the 7 years before ad 1009 with the 9 years following show an average increase of 6.1 ± 1.6 (s.d.)‰ (significant at the 99.6% confidence level). Such a pulse of 14C requires a total production of neutrons of 17.1 × 107n cm−2e, implying an input of 11.3 × 104 ergs cm−2e γ-ray energy. This requires the total supernova γ-ray energy (>10 MeV) to have been 1 × 1050 ergs.

Type
IV. 14C as a Tracer of the Dynamic Carbon Cycle in the Current Environment
Information
Radiocarbon , Volume 37 , Issue 2 , 1995 , pp. 599 - 604
Copyright
Copyright © the Department of Geosciences, The University of Arizona 

References

Berezinskii, V. S., Bulanov, S. V. and Dogiel, V. A. 1990 Astrophysics of Cosmic Rays. Amsterdam, North-Holland: 534 p.Google Scholar
Bacastow, R. and Keeling, C. D. 1973 Atmospheric carbon dioxide and radiocarbon in the natural carbon cycle: II. Changes from A.D. 1700 to 2070 as deduced from a geochemical model. In Woodwell, G. M. and Pecan, E. V., eds., Carbon and the Biosphere. Proceedings of the 24th Brookhaven Symposium in Biology, Upton, New York: 87135.Google Scholar
Chupp, E. L. 1976 Gamma-Ray Astronomy. Bingham, Massachussets, Reidel Publishing Co.: 317 p.Google Scholar
Damon, P. E., Burr, G., Cain, W. J. and Donahue, D. J. 1992 Anomalous 11-year Δ14C cycle at high latitudes? Radiocarbon 34(2): 235238.Google Scholar
International Atomic Energy Agency (IAEA) 1987 Handbook on Nuclear Activation Data. IAEA Technical Report Series 273. Vienna, IAEA: 811 p.Google Scholar
Kocharov, G. E., Dergachev, V. A., Sementsov, A. A., Romanova, E. N., Rumiantsev, S. A., Malanova, N. S. and Svezhentsev, I. U. S. 1974 Concentration of radiocarbon in tree-rings. In Proceedings of the 5th All-Union Meeting on Astrophysical Phenomena and Radiocarbon, Tbilisi. (Translated by Peterson, G. M., Center for Climatic Research, Institute for Environmental Studies, Madison, University of Wisconsin): 4760.Google Scholar
Lingenfelter, R. E. and Ramaty, R. 1970 Astrophysical and geophysical variation in C-14 production. In Olsson, I. U., ed., Radiocarbon Variations and Absolute Chronology. New York, John Wiley & Sons: 513537.Google Scholar
McHargue, L. R., Damon, P. E. and Donahue, D. J. 1995 Enhanced cosmic-ray production of 10Be coincident with the Mono Lake and Laschamp geomagnetic excursions. Geophysical Research Letters 22: 659662.Google Scholar
Murdin, P. 1985 Supernovae. 2nd ed. Cambridge, Cambridge University Press: 185 p.Google Scholar
Murdin, P. 1990 End in Fire: The Supernova in the Large Magellanic Cloud. Cambridge, Cambridge University Press: 251 p.Google Scholar
Raisbeck, G. M., Yiou, F., Bourles, D., Lorius, C., Jouzel, J. and Barkov, N. I. 1987 Evidence for two intervals of enhanced 10Be deposition in Antarctic ice during the last glacial period. Nature 326: 273277.Google Scholar
Reynolds, S. P. and Gilmore, D. M. 1986 Radio observations of the remnant of the supernova of A.D. 1006. I. Total intensity observations. Astronomical Journal 92: 11381144.Google Scholar
Stephenson, F. R. and Clark, D. H. 1976 Historical supernovas. Scientific American 234: 100107.Google Scholar
Stuiver, M. and Braziunas, T. F. 1993 Sun, ocean, climate and atmospheric CO2: An evaluation of causal and spectral relationships. The Holocene 3(4): 289305.Google Scholar
Stuiver, M. and Polach, H. 1977 Discussion: Reporting of 14C data. Radiocarbon 19(3): 355363.Google Scholar