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Late Ordovician geographic patterns of extinction compared with simulations of astrophysical ionizing radiation damage

Published online by Cambridge University Press:  08 April 2016

Adrian L. Melott
Affiliation:
Department of Physics and Astronomy, University of Kansas, Lawrence, Kansas 66045. E-mail: [email protected]
Brian C. Thomas
Affiliation:
Department of Physics and Astronomy, University of Kansas, Lawrence, Kansas 66045. E-mail: [email protected]

Extract

Terrestrial mass extinctions have been attributed to a wide range of causes. Some of them are external to Earth, such as bolide impacts (as widely discussed for the K/T boundary) and radiation events. Among radiation events, there are possible large solar flares, nearby supernovae, gamma-ray bursts (GRBs), and others. These have variable intensity, duration, and probability of occurrence, although some generalizations are possible in understanding their effects (Ejzak et al. 2007). Here we focus on gamma-ray bursts (Thorsett 1995; Scalo and Wheeler 2002), a proposed causal agent for the end-Ordovician extinction. These are the most remote and infrequent of events, but by virtue of their power, a threat approximately competitive with, for example, that of nearby supernovae. A GRB of the most powerful type (Woosley and Bloom 2006) is thought to result from a supernova at the end of stellar evolution for very massive stars with high rotational speed. Much of their energy is channeled into beams, or jets, which include very high energy electromagnetic energy, i.e., gamma-rays and X-rays. It is a testament to the power of these events, far across the observable universe, that they were first detected in the 1969–1970 results from monitoring satellites designed to detect nuclear explosions on Earth's surface. It was not until the 1990s, when the distance to the events became known, that their power became apparent. Several such events occur every day in the observable universe. Other kinds of events are also potentially damaging, such as so-called short bursts and solar flares, but rate information is only now beginning to clarify how much threat is likely from such sources.

Type
Matters of the Record
Copyright
Copyright © The Paleontological Society 

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References

Literature Cited

Arrigo, K. R., Lubin, D., van Dijken, G. L., Holm-Hansen, O., and Morrow, E. 2003. Impact of a deep ozone hole on Southern Ocean primary production. Journal of Geophysical Research 108:31543173. doi: 10.1029/2001JC001226CrossRefGoogle Scholar
Bancroft, B., Baker, N. J., and Blaustein, A. R. 2007. Effects of UVB radiation on marine and freshwater organisms: a synthesis through meta-analysis Ecology Letters 10:332.CrossRefGoogle ScholarPubMed
Blaustein, A. R., and Kiesecker, J. M. 2002. Complexity in conservation: lessons from the global decline of amphibian populations. Ecology Letters 5:597608. doi: 10.1046/J.1461–0248.2002.00352.x.Google Scholar
Blaustein, A. R., Hoffman, P. D., Hokit, D. G., Kiesecker, J. M., Walls, S. C., and Hays, J. B. 1994. UV-repair and resistance to solar UV-B in amphibian eggs: a link to population declines? Proceedings of the National Academy of Sciences USA 91:17911795.Google Scholar
Boelen, P., Obernostere, I., Vink, A. A., and Buma, A. G. J. 1999. Attenuation of biologically effective UV radiation in tropical Atlantic waters measured with a biochemical DNA dosimeter. Photochemistry and Photobiology 69:3440.CrossRefGoogle Scholar
Boelen, P., Post, A. F., Veldhuis, M. J. W., and Buma, A. G. J. 2002. Diel patterns of UVBR-induced DNA damage in picoplankton size fractions from the Gulf of Aqaba, Red Sea. Microbial Ecology 44:164174.Google Scholar
Boucher, N. P., and Prezelin, B. B. 1996. An in situ biological weighting function for UV inhibition of phytoplankton carbon fixation in the Southern Ocean. Marine Ecology Progress Series 144:223236.CrossRefGoogle Scholar
Brenchley, P. J., Carden, G. A., Hints, L., Kaljo, D., Marshall, J. D., Martma, T., Meidla, T., and Nõlvak, J. 2003. High-resolution stable isotope stratigraphy of Upper Ordovician sequences: constraints on the timing of bioevents and environmental changes associated with mass extinction and glaciation. Geological Society of America Bulletin 115:89104.Google Scholar
Cordero, E., Newman, P. A., Weaver, C., and Fleming, E. 2003. Chapter 6: Stratospheric dynamics and the transport of ozone and other trace gases, in stratospheric ozone: an electronic textbook. NASA: studying Earth's environment from space. http://www.ccpo.odu.edu/SEES/index.html.Google Scholar
Das, S., Lloyd, J. J., and Farr, P. M. 2001. Similar dose-response and persistence of erythema with broad-band and narrow-band ultraviolet B lamps. Journal of Investigative Dermatology 117:13181321. doi: 10.1046/j.0022-202x.2001.01511.xGoogle Scholar
Dermer, C. D. 2007. On gamma ray burst and blazar AGN origins of the ultra–high energy cosmic rays in light of first results from Auger. Invited talk, 30th International Cosmic Ray Conference, Merida, Mexico. arXiv:0711.2804.Google Scholar
Dermer, C. D., and Holmes, J. M. 2005. Cosmic rays from gamma-ray bursts in the Galaxy. Astrophysical Journal Letters 628:L21L24.CrossRefGoogle Scholar
Ejzak, L. M., Melott, A. L., Medvedev, M. V., and Thomas, B. C. 2007. Terrestrial consequences of spectral and temporal variability in ionizing photon events. Astrophysical Journal 654:373384.CrossRefGoogle Scholar
Fields, B. D., Hochmuth, K. A., and Ellis, J. 2005. Deep-ocean crusts as telescopes: using live radioisotopes to probe supernova nucleosynthesis. Astrophysical Journal 621:902907.CrossRefGoogle Scholar
Gehrels, N., Laird, C. M., Jackman, C. H., Cannizzo, J. K., Mattson, B. J., and Chen, W. 2003. Ozone depletion from nearby supernovae. Astrophysical Journal 585:11691176.Google Scholar
Herrmann, A. D., Hauptc, B. J., Patzkowsky, M. E., Seidov, D., and Slingerland, R. L. 2004. Response of Late Ordovician paleoceanography to changes in sea level, continental drift, and atmospheric pCO2: potential causes for long-term cooling and glaciation. Palaeogeography, Palaeoclimatology, Palaeoecology 210: 385–381.CrossRefGoogle Scholar
Hewitt, C. N., and Jackson, A. V. 2003. Handbook of atmospheric science. Blackwell, Oxford.CrossRefGoogle Scholar
Ioka, K., and Meszaros, P. 2008. Hypernova and gamma-ray burst remnants as TeV unidentified sources. arXiv:0901.0744.Google Scholar
Kouwenberg, J. H. M., and Lantoine, F. 2006. Effects of ultraviolet-B stressed diatom food on the reproductive output in Mediterranean Calanus helgolandicus (Crustacea; Copepoda). Journal of Experimental Marine Biology and Ecology 341:239253.CrossRefGoogle Scholar
Kouwenberg, J. H. M., Browman, H. I., Runge, J. A., Cullen, J. J., Davis, R. F., and Pierre, J.-F. St. 1999. Biological weighting of ultraviolet (280–400 nm) induced mortality in marine zooplankton and fish. II. Calanus finmarchicus (Copepoda) eggs. Marine Biology 134:285293.Google Scholar
Krug, A. Z., and Patzkowsky, M. E. 2004. Rapid recovery from the Late Ordovician mass extinction. Proceedings of the National Academy of Sciences USA 101:1760517610. doi: 10.1073/ pnas.0405199102.Google Scholar
Krug, A. Z., and Patzkowsky, M. E. 2007. Geographic variation in turnover and recovery from the Late Ordovician mass extinction. Paleobiology 33:435454.CrossRefGoogle Scholar
Llabreés, M., and Agustí, S. 2006. Picophytoplankton cell death induced by UV radiation: evidence for oceanic communities. Limnology and Oceanography 51:2129.Google Scholar
Madronich, S., McKenzie, R. L., Caldwell, M. M., and Björn, L. O. 1994. Changes in ultraviolet radiation reaching the earth's surface. In Stratospheric Ozone and Human Health Project, Center for International Earth Science Information Network, United Nations Environment Programme. http://sedac.ciesin.org/ozone/UNEP/chap1.html.Google Scholar
McCracken, K. G., Dreschhoff, G. A. M., Zeller, E. J., Smart, D. F., and Shea, M. A. 2001. Solar cosmic ray events for the period 1561–1994. 1. Identification in polar ice, 1561–1950. Journal of Geophysical Research 106:21,58521,598.Google Scholar
Melott, A. L. 2008. Long-term cycles in the history of life: periodic biodiversity in the paleobiology database. PLoS ONE3(12):e4044.Google Scholar
Melott, A. L., Lieberman, B. S., Laird, C. M., Martin, L. D., Medvedev, M. V., Thomas, B. C., Cannizzo, J. K., Gehrels, N., and Jackman, C. H. 2004. Did a gamma-ray burst initiate the late Ordovician mass extinction? International Journal of Astrobiology 3:5561. arXiv:astro-ph/0309415.Google Scholar
Melott, A. L., Thomas, B. C., Hogan, D. P., Ejzak, L. M., and Jackman, C. H. 2005. Climatic and biogeochemical effects of a galactic gamma ray burst. Geophysical Research Letters 32:L14808. doi: 10.1029/2005GL023073.Google Scholar
Melott, A. L., Krejci, A. J., Thomas, B. C., Medvedev, M. V., Murray, M. J., and Wilson, G. W. 2008. Atmospheric consequences of cosmic ray variability in the extragalactic shock model. Journal of Geophysical Research – Planets 113:E10007. doi: 10.1029/ 2008JE003206.CrossRefGoogle Scholar
Neale, P. J., Cullen, J. J., and Davis, R. F. 1998. Inhibition of marine photosynthesis by ultraviolet radiation: variable sensitivity of phytoplankton in the Weddell-Scotia Confluence during the austral spring. Limnology and Oceanography 43:433448.Google Scholar
Neale, P. J., Fritz, J. J., and Davis, R. F. 2001. Effects of UV on photosynthesis of Antarctic phytoplankton: models and their application to coastal and pelagic assemblages. Revista Chilena de Historia Natural 74:283289.Google Scholar
Rohde, R. A., and Muller, R. A. 2005. Cycles in fossil diversity. Nature 434:208210Google Scholar
Roopnarine, P.D. 2006. Extinction cascades and catastrophe in ancient food webs. Paleobiology 32:119.CrossRefGoogle Scholar
Royer, D. L. 2006. CO2-forced climate thresholds during the Phanerozoic. Geochimica et Cosmochimica Acta 70:56655676.Google Scholar
Savaglio, S. 2008. Low-mass and metal-poor gamma-ray burst host galaxies. In Hunt, L. K., Madden, S., and Schneider, R., eds. Low-metallicity star formation: from the first stars to dwarf galaxies. Proceedings, IAU Symposium 255, Rapallo, Italy, June 2008. arXiv:0808.2917v1.Google Scholar
Savaglio, , Glazebrook, S. K., and Le Borgne, D. 2009. The galaxy population hosting gamma-ray bursts. Astrophysical Journal 691:182211. doi: 10.1088/0004–637X/691/1/182.CrossRefGoogle Scholar
Scalo, J., and Wheeler, J. C. 2002. Astrophysical and astrobiological implications of gamma-ray burst properties. Astrophysical Journal 566:723737.Google Scholar
Scotese, C. R., and McKerrow, W. S. 1990. Revised world maps and introduction. In McKerrow, W. S. and Scotese, C. R., eds. Paleozoic paleogeography and biogeography. Geological Society of London Memoir 12:121.Google Scholar
Scotese, C. R., and McKerrow, W. S. 1991. Ordovician plate tectonic reconstructions. In Barnes, C. R. and Williams, S. H., eds. Advances in Ordovician geology. Geological Survey of Canada Paper 90-9:271282.Google Scholar
Setlow, R. B. 1974. The wavelengths in sunlight effective in producing skin cancer: a theoretical analysis. Proceedings of the National Academy of Sciences USA 71:33633366.Google Scholar
Smith, D. S., Scalo, J., and Wheeler, J. C. 2004. Transport of ionizing radiation in terrestrial-like exoplanet atmospheres. Icarus 171:229253.Google Scholar
Smith, R. C., et al. 1992. Ozone depletion: ultraviolet radiation and phytoplankton biology in Antarctic waters. Science 255:952959.Google Scholar
Stanek, K. Z. et al. 2006. Protecting life in the Milky Way: metals keep the GRBs away. Acta Astronomica 56:333345.Google Scholar
Thomas, B. C., and Honeyman, M. D. 2008. Amphibian nitrate stress as an additional terrestrial threat from astrophysical ionizing radiation events? Astrobiology 8:731733. doi: 10.1089/ast.2007.0262.CrossRefGoogle ScholarPubMed
Thomas, B. C., and Melott, A. L. 2006. Gamma-ray bursts and terrestrial planetary atmospheres. New Journal of Physics 8:120. doi: 10.1088/1367–2630/8/7/120.CrossRefGoogle Scholar
Thomas, B. C. et al. 2005. Gamma-ray bursts and the earth: exploration of atmospheric, biological, climatic, and biogeochemical effects. Astrophysical Journal 634:509533.Google Scholar
Thomas, B. C., Jackman, C. H., and Melott, A. L. 2007. Modeling atmospheric effects of the September 1859 solar flare. Geophysical Research Letters 34:L06810. doi: 10.1029/2006GL029174Google Scholar
Thomas, B. C., Melott, A. L., Fields, B. D., and Anthony-Twarog, B. J. 2008. Superluminous supernovae: no threat from β Carinae. Astrobiology 8:916. doi: 10.1089/ast.2007.0181.CrossRefGoogle Scholar
Thorsett, S. E. 1995. Terrestrial implications of cosmological gamma-ray burst models. Astrophysical Journal Letters 444:L53L55.Google Scholar
Woosley, S. E., and Bloom, J. S. 2006. The supernova–gamma-ray burst connection. Annual Reviews of Astronomy and Astrophysics 44:507556.Google Scholar