Cosmogenic Nuclides

Alan P. Dickin

doi:10.1017/9781316163009.015

Chapter 14 - Cosmogenic Nuclides

Published online by Cambridge University Press: 01 February 2018

Alan P. Dickin

Show author details

Alan P. Dickin: Affiliation:
McMaster University, Ontario

Book contents

Get access

Summary

A summary is not available for this content so a preview has been provided. Please use the Get access link above for information on how to access this content.

Image of the first page of this content. For PDF version, please use the ‘Save PDF’ preceeding this image.'

Type: Chapter
Information: Radiogenic Isotope Geology , pp. 363 - 406

DOI: https://doi.org/10.1017/9781316163009.015 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2018

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abreu, J. A., Beer, J., Steinhilber, F., Tobias, S. M. and Weiss, N. O. (2008). For how long will the current grand maximum of solar activity persist? Geophys. Res. Lett. 35, L20109 1–4.Google Scholar

Abreu, J. A., Beer, J., Ferriz-Mas, A., McCracken, K. G. and Steinhilber, F. (2012). Is there a planetary influence on solar activity? Astron. & Astrophys. 548, A88 1–9.Google Scholar

Adkins, J. F. and Boyle, E. A. (1997). Changing atmospheric D¹⁴C and the record of deep water paleoventilation ages. Paleoceanography 12, 337–44.CrossRef Google Scholar

Anderson, E. C. and Libby, W. F. (1951). World-wide distribution of natural radiocarbon. Phys. Rev. 81, 64–9.Google Scholar

Andree, M., Oeschger, H., Broecker, W. et al. (1986). Limits on ventilation rates for the deep ocean over the last 12,000 years. Climate Dynamics 1, 53–62.CrossRef Google Scholar

Andrews, J. N., Davis, S. N., Fabryka-Martin, J. et al. (1989). The in situ production of radioisotopes in rock matrices with particular reference to the Stripa granite. Geochim. Cosmochim. Acta 53, 1803–15.CrossRef Google Scholar

Arnold, J. R. (1956). Beryllium-10 produced by cosmic rays. Science 124, 584–5.CrossRef Google Scholar PubMed

Arnold, J. R. (1958). Trace elements and transport rates in the ocean. 2nd UN Conf. on Peaceful Uses of Atomic Energy 18, 344–6. IAEA.Google Scholar

Arnold, J. R. and Libby, W. F. (1949). Age determinations by radiocarbon content: Checks with samples of known age. Science 110, 678–80.CrossRef Google Scholar PubMed

Balco, G. and Rovey, C. W. (2008). An isochron method for cosmogenic-nuclide dating of buried soils and sediments. Amer. J. Sci. 308, 1083–114.CrossRef Google Scholar

Balco, G. and Rovey, C. W. (2010). Absolute chronology for major Pleistocene advances of the Laurentide Ice Sheet. Geology 38, 795–8.Google Scholar

Balco, G. and Shuster, D. L. (2009). ²⁶Al–¹⁰Be–²¹Ne burial dating. Earth Planet. Sci. Lett. 286, 570–5.CrossRef Google Scholar

Bard, E., Arnold, M., Fairbanks, R. G. and Hamelin, B. (1993). ²³⁰Th–²³⁴U and ¹⁴C ages obtained by mass spectrometry on corals. Radiocarbon 35, 191–9.Google Scholar

Bard, E., Arnold, M., Hamelin, B., Tisnerat-Laborde, N. and Cabioch, G. (1998). Radiocarbon calibration by means of mass spectrometric ²³⁰Th/²³⁴U and ¹⁴C ages of corals: an updated database including samples from Barbados, Mururoa and Tahiti. Radiocarbon 40, 1085–92.CrossRef Google Scholar

Bard, E., Arnold, M., Mangerud, J. et al. (1994). The North Atlantic atmosphere–sea surface ¹⁴C gradient during the Younger Dryas climatic event. Earth Planet. Sci. Lett. 126, 275–87.CrossRef Google Scholar

Bard, E. and Frank, M. (2006). Climate change and solar variability: What's new under the sun?. Earth Planet. Sci. Lett. 248, 1–14.Google Scholar

Bard, E., Hamelin, B., Fairbanks, R. G. and Zindler, A. (1990a). Calibration of the ¹⁴C timescale over the past 30,000 years using mass spectrometric U–Th ages from Barbados corals. Nature 345, 405–10.CrossRef Google Scholar

Bard, E., Hamelin, B., Fairbanks, R. G. et al. (1990b). U/Th and ¹⁴C ages of corals from Barbados and their use for calibrating the ¹⁴C timescale beyond 9000 years B.P. Nucl. Instr. Meth. in Phys. Res. B 52, 461–8.Google Scholar

Bard, E., Raisbeck, G. M., Yiou, F. and Jouzel, J. (1997). Solar modulation of cosmogenic nuclide production over the last millennium: comparison between ¹⁴C and ¹⁰Be records. Earth Planet. Sci. Lett. 150, 453–62.CrossRef Google Scholar

Baumgartner, S., Beer, J., Masarik, J. et al. (1998). Geomagnetic modulation of the ³⁶Cl flux in the GRIP ice core, Greenland. Science 279, 1330–2.Google Scholar

Baxter, M. S. and Farmer, J. G. (1973). Radiocarbon: short-term variations. Earth Planet. Sci. Lett. 20, 295–9.Google Scholar

Bayes, T. and Price, R. (1763). An essay towards solving a problem in the doctrine of chances. Phil. Trans. 53, 370–418.Google Scholar

Beck, J. W., Richards, D. A., Edwards, R. L. et al. (2001). Extremely large variations of atmospheric ¹⁴C concentration during the last glacial period. Science 292, 2453–8.CrossRef Google Scholar PubMed

Beer, J., McCracken, K. G., Abreu, J., Heikkilä, U. and Steinhilber, F. (2013). Cosmogenic radionuclides as an extension of the neutron monitor era into the past: potential and limitations. Space Sci. Rev. 176, 89–100.Google Scholar

Beer, J., Andree, M., Oeschger, H. et al. (1984). The Camp Century ¹⁰Be record: implications for long-term variations of the geomagnetic dipole moment. Nucl. Instr. Meth. in Phys. Res. B 5, 380–4.Google Scholar

Beer, J., Oeschger, H., Finkel, R. C. et al. (1985). Accelerator measurements of ¹⁰Be: the 11 year solar cycle. Nucl. Instr. Meth. in Phys. Res. B 10, 415–18.Google Scholar

Beer, J., Siegenthaler, U., Bonani, G. et al. (1988). Information on past solar activity and geomagnetism from ¹⁰Be in the Camp Century ice core. Nature 331, 675–9.CrossRef Google Scholar

Bentley, H. W., Phillips, F. M., Davis, S. N. et al. (1982). Thermonuclear ³⁶Cl pulse in natural water. Nature 300, 737–40.CrossRef Google Scholar

Bentley, H. W., Phillips, F. M., Davis, S. N. et al. (1986). Chlorine 36 dating of very old groundwaters, 1, The Great Artesian Basin, Australia. Water Resources Res. 22, 1991–2002.CrossRef Google Scholar

Bierman, P., Gillespie, A., Caffee, M. and Elmore, D. (1995). Estimating erosion rates and exposure ages with ³⁶Cl produced by neutron activation. Geochim. Cosmochim. Acta 59, 3779–98.Google Scholar

Broecker, W., Barker, S., Clark, E. et al. (2004). Ventilation of the glacial deep Pacific Ocean. Science 306, 1169–72.Google Scholar

Broecker, W., Clark, E. and Barker, S. (2008). Near constancy of the Pacific Ocean surface to mid-depth radiocarbon-age difference over the last 20 kyr. Earth Planet. Sci. Lett. 274, 322–6.CrossRef Google Scholar

Broecker, W. S. and Denton, G. H. (1989). The role of ocean–atmosphere reorganizations in glacial cycles. Geochim. Cosmochim. Acta 53, 2465–501.Google Scholar

Broecker, W. S., Gerard, R., Ewing, M. and Heezen, B. C. (1960). Natural radiocarbon in the Atlantic Ocean. J. Geophys. Res. 65, 2903–31.Google Scholar

Broecker, W. S. and Peng, T. H. (1982). Tracers in the Sea. Lamont-Doherty Geol. Obs. 690 pp.Google Scholar

Brown, E. T., Edmond, J. M., Raisbeck, G. M. et al. (1992). Beryllium isotope geochemistry in tropical basins. Geochim. Cosmochim. Acta 56, 1607–24.Google Scholar

Brown, L., Klein, J. and Middleton, R. (1985). Anomalous isotopic concentrations in the sea off Southern California. Geochim. Cosmochim. Acta 49, 153–7.Google Scholar

Brown, L., Klein, J., Middleton, R., Sacks, I. S. and Tera, F. (1982). ¹⁰Be in island-arc volcanoes and implications for subduction. Nature 299, 718–20.Google Scholar

Brown, L., Stensland, G. J., Klein, J. and Middleton, R. (1989). Atmospheric deposition of ⁷Be and ¹⁰Be. Geochim. Cosmochim. Acta 53, 135–42.CrossRef Google Scholar

Bruns, M., Rhein, M., Linick, T. W. and Suess, H. E. (1983). The atmospheric ¹⁴C level in the 7th millennium BC. P.A.C.T. (Physical And Chemical Techniques in Archaeology) 8, 511–16.Google Scholar

Bucha, V. and Neustupny, E. (1967). Changes in the Earth's magnetic field and radiocarbon dating. Nature 215, 261–3.CrossRef Google Scholar

Buck, C. E., Litton, C. D. and Smith, A. F. (1992). Calibration of radiocarbon results pertaining to related archaeological events. J. Archaeological Sci. 19, 497–512.Google Scholar

Burke, A., and Robinson, L. F. (2012). The Southern Ocean's role in carbon exchange during the last deglaciation. Science 335, 557–61.Google Scholar

Campin, J.-M., Fichefet, T. and Duplessy, J.-C. (1999). Problems with using radiocarbon to infer ocean ventilation rates for past and present climates. Earth Planet. Sci. Lett. 165, 17–24.Google Scholar

Chengde, S., Beer, J., Tungsheng, L. et al. (1992). ¹⁰Be in Chinese loess. Earth Planet. Sci. Lett. 109, 169–77.Google Scholar

Chmeleff, J., von Blanckenburg, F., Kossert, K. and Jakob, D. (2010). Determination of the ¹⁰Be half-life by multicollector ICP–MS and liquid scintillation counting. Nucl. Instr. Meth. in Phys. Res. B 268, 192–9.Google Scholar

Cohen, T. J. and Lintz, P. R. (1974). Long term periodicities in the sunspot cycle. Nature 250, 398–400.Google Scholar

Craig, H. (1954). Carbon-13 in plants and the relationships between carbon-13 and carbon-14 variations in nature. J. Geol. 62, 115–49.CrossRef Google Scholar

Craig, H. (1957). Isotopic standards for carbon and oxygen and correction factors for mass-spectrometric analysis of carbon dioxide. Geochim. Cosmochim. Acta 12, 133–49.Google Scholar

Davis, R. and Schaeffer, O. A. (1955). Chlorine-36 in Nature. Ann. N. Y. Acad. Sci. 62, 105–22.Google Scholar

De Jong, A. F. M., Mook, W. G. and Becker, B. (1979). Confirmation of the Suess wiggles: 3200–3700 BC. Nature 280, 48–9.Google Scholar

De Vries, H. (1958). Variation in concentration of radiocarbon with time and location on Earth. Proc. Konikl. Ned. Akad. Wetenschap B 61, 94–102.Google Scholar

De Vries, H. and Barendsen, G. W. (1953). Radiocarbon dating by a proportional counter filled with carbon dioxide. Physica 19, 987–1003.CrossRef Google Scholar

DeVries, T. and Primeau, F. (2010). An improved method for estimating water-mass ventilation age from radiocarbon data. Earth and Planetary Science Letters 295, 367–78.CrossRef Google Scholar

Druffel, E. M. (1996). Post-bomb radiocarbon records of surface corals from the tropical Atlantic Ocean. Radiocarbon 38, 563–72.Google Scholar

Eddy, J. A. (1976). The Maunder minimum. Science 192, 1189–202.Google Scholar

Eddy, J. A. (1977). Climate and the changing sun. Climate Change 1, 173–90.Google Scholar

Edwards, R. L., Beck, J. W., Burr, G. S. et al. (1993a). A large drop in atmospheric ¹⁴C/¹²C and reduced melting in the Younger Dryas, documented with ²³⁰Th ages of corals. Science 260, 962–8.Google Scholar

Edwards, C. M. H., Morris, J. D. and Thirlwall, M. F. (1993b). Separating mantle from slab signatures in arc lavas using B/Be and radiogenic isotope systematics. Nature 362, 530–3.Google Scholar

Elmore, D., Gove, H. E., Ferraro, R. et al. (1980). Determination of ¹²⁹I using tandem accelerator mass spectrometry. Nature 286, 138–40.Google Scholar

Elmore, D., Tubbs, L. E., Newman, D. et al. (1982). ³⁶Cl bomb pulse measured in a shallow ice core from Dye 3, Greenland. Nature 300, 735–7.CrossRef Google Scholar

Elsasser, W., Ney, E. P. and Winckler, J. R. (1956). Cosmic-ray intensity and geomagnetism. Nature 178, 1226–7.Google Scholar

Evans, J. C., Rancitelli, L. A. and Reeves, J. H. (1979). ²⁶Al content of Antarctic meteorites: implications for terrestrial ages and bombardment history. Proc. 10th Lunar Planet. Sci. Conf., 1061–72.Google Scholar

Evans, J. C. and Reeves, J. H. (1987). ²⁶Al survey of Antarctic meteorites. Earth Planet. Sci. Lett. 82, 223–30.Google Scholar

Fabryka-Martin, J., Bentley, H., Elmore, D. and Airey, P. L. (1985). Natural iodine-129 as an environmental tracer. Geochim. Cosmochim. Acta 49, 337–47.Google Scholar

Fabryka-Martin, J., Davis, S. N. and Elmore, D. (1987). Applications of ¹²⁹I and ³⁶Cl in hydrology. Nucl. Instr. Meth. in Phys. Res. B 29, 361–71.Google Scholar

Fabryka-Martin, J., Davis, S. N., Elmore, D. and Kubik, P. W. (1989). In situ production and migration of ¹²⁹I in the Stripa granite, Sweden. Geochim. Cosmochim. Acta 53, 1817–23.CrossRef Google Scholar

Fan, C. Y., Chen, T. M., Yun, S. X. and Dai, K. M. (1986). Radiocarbon activity variation in dated tree rings grown in Mackenzie delta. Radiocarbon 28, 300–5.CrossRef Google Scholar

Fehn, U. (2012). Tracing crustal fluids: Applications of natural ¹²⁹I and ³⁶Cl. Ann. Rev. Earth Planet. Sci. 40, 45.Google Scholar

Fehn, U., Holdren, G. R., Elmore, D. et al. (1986). Determination of natural and anthropogenic ¹²⁹I in marine sediments. Geophys. Res. Lett. 13, 137–9.CrossRef Google Scholar

Fehn, U., Moran, J. E., Snyder, G. T. and Muramatsu, Y. (2007a). The initial ¹²⁹I/I ratio and the presence of ‘old’ iodine in continental margins. Nucl. Instr. Meth. in Phys. Res. B 259, 496–502.Google Scholar

Fehn, U., Snyder, G. T. and Muramatsu, Y. (2007b). Iodine as a tracer of organic material: ¹²⁹I results from gas hydrate systems and fore arc fluids. J. Geochem. Explor. 95, 66–80.Google Scholar

Ferguson, C. W. (1970). Dendrochronology of Bristlecone pine, Pinus aristata. Establishment of a 7484-year chronology in the White Mountains of eastern-central California, USA. In: Olsson, I. U. (Ed.) Radiocarbon Variations and Absolute Chronology, Proc. 12th Nobel Symp. Wiley, pp. 571–93.Google Scholar

Ferguson, C. W. and Graybill, D. A. (1983). Dendrochronology of Bristlecone pine: a progress report. Radiocarbon 25, 287–8.Google Scholar

Feulner, G. and Rahmstorf, S. (2010). On the effect of a new grand minimum of solar activity on the future climate on Earth. Geophys. Res. Lett. 37, L05707, 1–5.Google Scholar

Fink, D., Middleton, R., Klein, J. and Sharma, P. (1990). ⁴¹Ca measurement by accelerator mass spectrometry and applications. Nucl. Instr. Meth. in Phys. Res. B 47, 79–96.Google Scholar

Fleitmann, D., Burns, S. J., Mudelsee, M. et al. (2003). Holocene forcing of the Indian monsoon recorded in a stalagmite from southern Oman. Science 300, 1737–9.Google Scholar

Forbush, S. E. (1954). Worldwide cosmic-ray variations, 1937–1952. J. Geophys. Res. 59, 525–42.Google Scholar

Frank, M., Schwarz, B., Baumann, S. et al. (1997). A 200 ka record of cosmogenic radionuclide production rate and geomagnetic field intensity from ¹⁰Be in globally stacked deep-sea sediments. Earth Planet. Sci. Lett. 149, 121–9.Google Scholar

Galbraith, E. D., Jaccard, S. L., Pedersen, T. F. et al. (2007). Carbon dioxide release from the North Pacific abyss during the last deglaciation. Nature 449, 890–3.Google Scholar

Godwin, H. (1962). Half-life of radiocarbon. Nature 195, 984.Google Scholar

Goldberg, E. D. and Arrhenius, G. O. S. (1958). Chemistry of Pacific pelagic sediments. Geochim. Cosmochim. Acta 13, 153–212.Google Scholar

Goldstein, S. J., Lea, D. W., Chakraborty, S., Kashgarian, M. and Murrell, M. T. (2001). Uranium-series and radiocarbon geochronology of deep-sea corals: implications for Southern Ocean ventilation rates and the ocean carbon cycle. Earth Planet. Sci. Lett. 193, 167–82.CrossRef Google Scholar

Goslar, T., Arnold, M., Bard, E. et al. (1995). High concentration of atmospheric ¹⁴C during the Younger Dryas cold episode. Nature 377, 414–17.Google Scholar

Gove, H. E. (1987). Tandem-accelerator mass-spectrometry measurements of ³⁶Cl, ¹²⁹I and osmium isotopes in diverse natural samples. Phil. Trans. Roy. Soc. Lond. A 323, 103–19.Google Scholar

Graf, T., Kohl, C. P., Marti, K. and Nishiizumi, K. (1991). Cosmic-ray produced neon in Antarctic rocks. Geophys. Res. Lett. 18, 203–6.Google Scholar

Granger, D. E., Fabel, D. and Palmer, A. N. (2001). Pliocene–Pleistocene incision of the Green river, Kentucky, determined from radioactive decay of cosmogenic ²⁶Al and ¹⁰Be in Mammoth Cave sediments. GSA Bulletin 113, 825–36.Google Scholar

Granger, D. E., Gibbon, R. J., Kuman, K. et al. (2015). New cosmogenic burial ages for Sterkfontein Member 2 Australopithecus and Member 5 Oldowan. Nature 522, 85–8.Google Scholar

Granger, D. E. and Muzikar, P. F. (2001). Dating sediment burial with in situ-produced cosmogenic nuclides: theory, techniques, and limitations. Earth Planet. Sci. Lett. 188, 269–81.Google Scholar

Gray, L. J., Beer, J., Geller, M. et al. (2010). Solar influences on climate. Rev. Geophys. 48, RG4001, 1–53.Google Scholar

Guyodo, Y. and Valet, J. P. (1996). Relative variations in geomagnetic intensity from sedimentary records: the past 200,000 years. Earth Planet. Sci. Lett. 143, 23–36.Google Scholar

Hammer, C. U., Clausen, H. B. and Tauber, H. (1986). Ice-core dating of the Pleistocene/Holocene boundary applied to a calibration of the ¹⁴C time scale. Radiocarbon 28, 284–91.CrossRef Google Scholar

Heisinger, B., Lal, D., Jull, A. T. et al. (2002). Production of selected cosmogenic radionuclides by muons: 1. Fast muons. Earth Planet. Sci. Lett. 200, 345–55.Google Scholar

Henning, W. (1987). Accelerator mass spectrometry of heavy elements: ³⁶Cl to ²⁰⁵Pb. Phil. Trans. Roy. Soc. Lond. A 323, 87–99.Google Scholar

Hillam, J., Groves, C. M., Brown, D. M. et al. (1990). Dendrochronology of the English Neolithic. Antiquity 64, 210–20.Google Scholar

Hoffmann, D. L., Beck, J. W., Richards, D. A. et al. (2010). Towards radiocarbon calibration beyond 28 ka using speleothems from the Bahamas. Earth Planet. Sci. Lett. 289, 1–10.Google Scholar

Hofmann, H. J., Beer, J., Bonani, G. et al. (1987). ¹⁰Be half-life and AMS-standards. Nucl. Instr. Meth. in Phys. Res. B 29, 32–6.Google Scholar

Hua, Q., Barbetti, M., Fink, D. et al. (2009). Atmospheric ¹⁴C variations derived from tree rings during the early Younger Dryas. Quaternary Sci. Rev. 28, 2982–90.CrossRef Google Scholar

Huber, B. (1970). Dendrochronology of central Europe. In: Olsson, I. U. (Ed.) Radiocarbon Variations and Absolute Chronology, Proc. 12th Nobel Symp. Wiley, pp. 233–5.Google Scholar

Hughen, K. A., Overpeck, J. T., Lehman, S. J. et al. (1998). Deglacial changes in ocean circulation from an extended radiocarbon calibration. Nature 391, 65–8.Google Scholar

Jull, A. T. and Burr, G. S. (2006). Accelerator mass spectrometry: Is the future bigger or smaller? Earth Planet. Sci. Lett. 243, 305–25.Google Scholar

Kamen, M. D. (1963). Early history of carbon-14. Science 140, 584–90.Google Scholar

Keigwin, L. D. and Lehman, S. J. (2015). Radiocarbon evidence for a possible abyssal front near 3.1 km in the glacial equatorial Pacific Ocean. Earth Planet. Sci. Lett. 425, 93–104.CrossRef Google Scholar

Kelly, P. M. and Wigley, T. M. L. (1992). Solar cycle length, greenhouse forcing and global climate. Nature 360, 328–30.Google Scholar

Key, R., Quay, P. D., Jones, G. A. et al. (1996). WOCE AMS radiocarbon I: Pacific Ocean results (P6, P16, P17). Radiocarbon 38, 425–518.Google Scholar

Kieser, W. E., Beukens, R. P., Kilius, L. R., Lee, H. W. and Litherland, A. E. (1986). Isotrace radiocarbon analysis – equipment and procedures. Nucl. Instr. Meth. in Phys. Res. B 15, 718–21.Google Scholar

Kitagawa, H. and van der Plicht, J. (1998). Atmospheric radiocarbon calibration to 45,000 yr B.P.: Late glacial fluctuations and cosmogenic isotope production. Science 279, 1187–90.Google Scholar

Klein, J., Fink, D., Middleton, R., Nishiizumi, K. and Arnold, J. (1991). Determination of the half-life of ⁴¹Ca from measurements of Antarctic meteorites. Earth Planet. Sci. Lett. 103, 79–83.Google Scholar

Kober, F., Ivy-Ochs, S., Schlunegger, F. et al. (2007). Denudation rates and a topography-driven rainfall threshold in northern Chile: multiple cosmogenic nuclide data and sediment yield budgets. Geomorphology 83, 97–120.CrossRef Google Scholar

Kok, Y. S. (1999). Climatic influence in NRM and ¹⁰Be-derived geomagnetic paleointensity data. Earth Planet. Sci. Lett. 166, 105–19.Google Scholar

Korschinek, G., Bergmaier, A., Faestermann, T. et al. (2010). A new value for the half-life of ¹⁰Be by heavy-ion elastic recoil detection and liquid scintillation counting. Nucl. Instr. Meth. in Phys. Res. B 268, 187–91.Google Scholar

Krivova, N. A., Vieira, L. E. A. and Solanki, S. K. (2010). Reconstruction of solar spectral irradiance since the Maunder minimum. J. Geophys. Res.: Space Phys. 115, A12112, 1–11.Google Scholar

Kromer, B., Friedrich, M., Hughen, K. A. et al. (2004). Late glacial ¹⁴C ages from a floating, 1382-ring pine chronology. Radiocarbon 46, 1203–9.Google Scholar

Ku, T. L., Wang, L., Luo, S. and Southon, J. R. (1995). ²⁶Al in seawater and ²⁶Al/¹⁰Be as paleo-flux tracer. Geophys. Res. Lett. 22, 2163–6.CrossRef Google Scholar

Ku, T. L., Kusakabe, M., Measures, C. I. et al. (1990). Beryllium isotope distribution in the western North Atlantic: a comparison to the Pacific. Deep-Sea Res. 37, 795–808.Google Scholar

Kusakabe, M., Ku, T. L., Southon, J. R. et al. (1987). The distribution of ¹⁰Be and ⁹Be in ocean water. Nucl. Instr. Meth. in Phys. Res. B 29, 306–10.Google Scholar

Labrie, D. and Reid, J. (1981). Radiocarbon dating by infrared laser spectroscopy. Appl. Phys. 24, 381–6.CrossRef Google Scholar

Laj, C., Kissel, C., Mazaud, A. et al.. (2002). Geomagnetic field intensity, North Atlantic Deep Water circulation and atmospheric Δ 14 C during the last 50 kyr. Earth Planet. Sci. Lett. 200, 177–90.Google Scholar

Laken, B. A., Pallé, E., Čalogović, J. and Dunne, E. M. (2012). A cosmic ray–climate link and cloud observations. J. Space Weather Space Climate 2, A18.Google Scholar

Lal, D. (1988). In situ-produced cosmogenic isotopes in terrestrial rocks. Ann. Rev. Earth Planet. Sci. 16, 355–88.Google Scholar

Lal, D. (1991). Cosmic ray labeling of erosion surfaces: in situ nuclide production rates and erosion models. Earth Planet. Sci. Lett. 104, 424–39.Google Scholar

Lal, D. (2007). Recycling of cosmogenic nuclides after their removal from the atmosphere; special case of appreciable transport of ¹⁰Be to polar regions by aeolian dust. Earth Planet. Sci. Lett. 264, 177–87.Google Scholar

Lal, D. and Peters, B. (1967). Cosmic-ray produced radioactivity on the Earth. In: Handbook of Physics 46/2. Springer, pp. 551–612.Google Scholar

Lao, Y., Anderson, R. F., Broecker, W. S. et al. (1992). Increased production of cosmogenic ¹⁰Be during the Last Glacial Maximum. Nature 357, 576–8.Google Scholar

Lean, J., Skumanich, A. and White, O. (1992). Estimating the Sun's radiative output during the Maunder Minimum. Geophys. Res. Lett. 19, 1591–4.Google Scholar

Lee, H. W., Galindo-Uribarri, A., Chang, K. H., Kilius, L. R. and Litherland, A. E. (1984). The ¹²CH₂⁺² molecule and radiocarbon dating by accelerator mass spectrometry. Nucl. Instrum. Meth. in Phys. Res. B 5, 208–10.Google Scholar

Libby, W. F. (1952). Radiocarbon Dating. University of Chicago Press, 124 pp.Google Scholar

Libby, W. F. (1970). Ruminations on radiocarbon dating. In: Olsson, I. U. (Ed.) Radiocarbon Variations and Absolute Chronology, Proc. 12th Nobel Symp. Wiley, pp. 629–40.Google Scholar

Litherland, A. E. (1987). Fundamentals of accelerator mass spectrometry. Phil. Trans. Roy. Soc. Lond. A 323, 5–21.Google Scholar

Litherland, A. E., Zhao, X. L. and Kieser, W. E. (2011). Mass spectrometry with accelerators. Mass Spec. Rev. 30, 1037–72.Google Scholar

Liu, B., Phillips, F. M., Fabryka-Martin, J. T., Fowler, M. M. and Stone, W. D. (1994). Cosmogenic ³⁶Cl accumulation in unstable landforms 1. effects of the thermal neutron distribution. Water Resour. Res. 30, 3115–25.Google Scholar

Lockwood, M. (2010). Solar change and climate: an update in the light of the current exceptional solar minimum. Proc. Roy. Soc. A 466, 303–29.Google Scholar

Mahara, Y., Habermehl, M. A., Hasegawa, T. et al. (2009). Groundwater dating by estimation of groundwater flow velocity and dissolved ⁴He accumulation rate calibrated by ³⁶Cl in the Great Artesian Basin, Australia. Earth Planet. Sci. Lett. 287, 43–56.Google Scholar

Mangini, A., Segl, M., Bonani, G. et al. (1984). Mass-spectrometric ¹⁰Be dating of deep-sea sediments applying the Zurich tandem accelerator. Nucl. Instr. Meth. in Phys. Res. B 5, 353–8.Google Scholar

Mann, M. E. and Park, J. (1994). Global-scale modes of surface temperature variability on interannual to century timescales. J. Geophys. Res.: Atm. 99, 25819–33.Google Scholar

Marchitto, T. M., Lehman, S. J., Ortiz, J. D., Flückiger, J. and van Geen, A. (2007). Marine radiocarbon evidence for the mechanism of deglacial atmospheric CO₂ rise. Science, 316, 1456–9.Google Scholar

Marrero, S. M., Phillips, F. M., Caffee, M. W. and Gosse, J. C. (2016). CRONUS-Earth cosmogenic ³⁶Cl calibration. Quaternary Geochron. 31, 199–219.Google Scholar

Maunder, E. W. (1922). The sun and sun-spots, 1820–1920. Monthly Notices Roy. Astron. Soc. 82, 534–43.Google Scholar

Maycock, A. C., Ineson, S., Gray, L. J. et al. (2015). Possible impacts of a future grand solar minimum on climate: Stratospheric and global circulation changes. J. Geophys. Res.: Atm. 120, 9043–58.Google Scholar

Mazaud, A., Laj, C., Bard, E., Arnold, M. and Tric, E. (1991). Geomagnetic field control of ¹⁴C production over the last 80 ka: implications for the radiocarbon time-scale. Geophys Res. Lett. 18, 1885–8.Google Scholar

McCorkell, R., Fireman, E. L. and Langway, C. C. (1967). Aluminium-26 and Beryllium-10 in Greenland Ice. Science 158, 1690–2.Google Scholar

McCracken, K. G., Beer, J. and Steinhilber, F. (2014). Evidence for planetary forcing of the cosmic ray intensity and solar activity throughout the past 9400 years. Solar Phys. 289, 3207–29.Google Scholar

Measures, C. I. and Edmond, J. M. (1982). Beryllium in the water column of the central North Pacific. Nature 297, 51–3.Google Scholar

Merrill, J. R., Lyden, E. F. X., Honda, M. and Arnold, J. R. (1960). The sedimentary geochemistry of the beryllium isotopes. Geochim. Cosmochim. Acta 18, 108–29.Google Scholar

Middleton, R. and Klein, J. (1987). ²⁶Al: measurement and applications. Phil. Trans. Roy. Soc. Lond. A 323, 121–43.Google Scholar

Mitchell, S. G., Matmon, A., Bierman, P. R. et al. (2001). Displacement history of a limestone normal fault scarp, northern Israel, from cosmogenic ³⁶Cl. J. Geophys. Res. 106, 4247–64.Google Scholar

Monaghan, M. C., Klein, J. and Measures, C. I. (1988). The origin of ¹⁰Be in island-arc volcanic rocks. Earth Planet. Sci. Lett. 89, 288–98.Google Scholar

Monnin, E., Indermühle, A., Dällenbach, A. et al. (2001). Atmospheric CO₂ concentrations over the last glacial termination. Science 291, 112–14.Google Scholar

Mook, W. G. and Streurman, H. J. (1983). Physical and chemical aspects of radiocarbon dating. P.A.C.T. (Physical And Chemical Techniques in Archaeology) 8, 31–55.Google Scholar

Moran, J. E., Fehn, U. and Teng, R. T. (1998). Variations in ¹²⁹I/¹²⁷I ratios in recent marine sediments: evidence for a fossil organic component. Chem. Geol. 152, 193–203.Google Scholar

Morris, J. D., Leeman, W. P. and Tera, F. (1990). The subducted component in island arc lavas: constraints from Be isotopes and B–Be systematics. Nature 344, 31–6.CrossRef Google Scholar PubMed

Morris, J. D. and Tera, F. (1989). ¹⁰Be and ⁹Be in mineral separates and whole-rocks from island arcs: implications for sediment subduction. Geochim. Cosmochim. Acta 53, 3197–206.Google Scholar

Naylor, J. C. and Smith, A. F. M. (1988). An archaeological inference problem. J. Amer. Stat. Assoc. 83, 588–95.Google Scholar

Neff, U., Burns, S. J., Mangini, A. et al. (2001). Strong coherence between solar variability and the monsoon in Oman between 9 and 6 kyr ago. Nature 411, 290–3.Google Scholar

Nishiizumi, K., Arnold, J. R., Elmore, D et al. (1979). Measurements of ³⁶Cl in Antarctic meteorites and Antarctic ice using a van de Graaff accelerator. Earth Planet. Sci. Lett. 45, 285–92.Google Scholar

Nishiizumi, K., Elmore, D. and Kubik, P. W. (1989a). Update on terrestrial ages of Antarctic meteorites. Earth Planet. Sci. Lett. 93, 299–313.Google Scholar

Nishiizumi, K., Kohl, C. P., Arnold, J. R. et al. (1991a). Cosmic-ray produced ¹⁰Be and ²⁶Al in Antarctic rocks: exposure and erosion history. Earth Planet. Sci. Lett. 104, 440–54.Google Scholar

Nishiizumi, K., Kohl, C. P., Shoemaker, J. R. et al. (1991b). In situ ¹⁰Be and ²⁶Al exposure ages at Meteor Crater, Arizona. Geochim. Cosmochim. Acta 55, 2699–703.Google Scholar

Nishiizumi, K., Lal, D., Klein, J., Middleton, R. and Arnold, J. R. (1986). Production of ¹⁰Be and ²⁶Al by cosmic rays in terrestrial quartz in situ and implications for erosion rates. Nature 319, 134–6.Google Scholar

Nishiizumi, K., Winterer, E. L., Kohl, C. P. et al. (1989b). Cosmic ray production rates of ¹⁰Be and ²⁶Al in quartz from glacially polished rocks. J. Geophys. Res. 94, 17 907–15.Google Scholar

Nydal, R. (2000). Radiocarbon in the ocean. Radiocarbon 42, 81–98.Google Scholar

Oeschger, H., Houtermans, J., Loosli, H. and Wahlen, M. (1970). The constancy of cosmic radiation from isotope studies in meteorites and on the Earth. In: Olsson, I. U. (Ed.) Radiocarbon Variations and Absolute Chronology, Proc. 12th Nobel Symp. Wiley, pp. 471–98.Google Scholar

Oktay, S. D., Santschi, P. H., Moran, J. E. and Sharma, P. (2000). The ¹²⁹I bomb pulse recorded in Mississippi River Delta sediments: results from isotopes of I, Pu, Cs, Pb, and C. Geochim. Cosmochim. Acta 64, 989–96.Google Scholar

Olsson, I. U., El-Daoushy, M. F. A. F., Abdel-Mageed, A. I. and Klasson, M. (1974). A comparison of different methods for pretreatment of bones. Geol. Foren. Stockh. Forhandl. 96, 171–81.Google Scholar

Olsson, I. U. (1980). ¹⁴C in extractives from wood. Radiocarbon 22, 515–24.CrossRef Google Scholar

Ostlund, H. G. and Rooth, C. G. H. (1990). The North Atlantic tritium and radiocarbon transients 1972–1983. J. Geophys. Res. 95, 20 147–65.Google Scholar

Pavich, M. J., Brown, L., Valette-Silver, J. N., Klein, J. and Middleton, R. (1985). ¹⁰Be analysis of a Quaternary weathering profile in the Virginia Piedmont. Geology 13, 39–41.Google Scholar

Pearson, G. W., Pilcher, J. R., Baillie, M. G. L. and Hillam, J. (1977). Absolute radiocarbon dating using a low altitude European tree-ring calibration. Nature 270, 25–8.Google Scholar

Phillips, F. M., Argento, D. C., Balco, G. et al. (2016). The CRONUS-Earth project: a synthesis. Quaternary Geochron. 31, 119–54.Google Scholar

Phillips, F. M., Leavy, B. D., Jannik, N. O., Elmore, D. and Kubik, P. W. (1986). The accumulation of cosmogenic chlorine-36 in rocks: a method for surface exposure dating. Science 231, 41–3.Google Scholar

Phillips, F. M., Mattick, J. L. and Duval, T. A. (1988). Chlorine 36 and tritium from nuclear weapons fallout as tracers for long-term liquid and vapour movement in desert soils. Water Resour. Res. 24, 1877–91.Google Scholar

Phillips, F. M., Zreda, M. G., Gosse, J. C. et al. (1997). Cosmogenic ³⁶Cl and ¹⁰Be ages of Quaternary glacial and fluvial deposits of the Wind River Range, Wyoming. GSA Bull. 109, 1453–63.Google Scholar

Plummer, M. A., Phillips, F. M., Fabryka-Martin, J. et al. (1997). Chlorine-36 in fossil rat urine: an archive of cosmogenic nuclide deposition during the past 40,000 years. Science 277, 538–41.Google Scholar

Purser, K. H., Liebert, R. B., Litherland, A. E. et al. (1977). An attempt to detect stable N-ions from a sputter ion source and some implications of the results for the design of tandems for ultra-sensitive carbon analysis. Rev. Phys. Appl. 12, 1487–92.Google Scholar

Raisbeck, G. M., Yiou, F., Fruneau, M., Lieuvin, M. and Loiseaux, J. M. (1978). Measurements of ¹⁰Be in 1,000- and 5,000-year-old Antarctic ice. Nature 275, 731–3.Google Scholar

Raisbeck, G. M., Yiou, F., Fruneau, M. et al. (1979). Deposition rate and seasonal variations in precipitation of cosmogenic ¹⁰Be. Nature 282, 279–80.CrossRef Google Scholar

Raisbeck, G. M., Yiou, F., Fruneau, M. et al. (1981a). Cosmogenic ¹⁰Be concentrations in Antarctic ice during the past 30,000 years. Nature 292, 825–6.Google Scholar

Raisbeck, G. M., Yiou, F., Fruneau, M. et al. (1980). ¹⁰Be concentration and residence time in the deep ocean. Earth Planet. Sci. Lett. 51, 275–8.Google Scholar

Raisbeck, G. M., Yiou, F. and Zhou, S. Z. (1994). Palaeointensity puzzle. Nature 371, 207–8.Google Scholar

Ralph, E. K. (1971). Carbon-14 dating. In: Michael, H. N. and Ralph, E. K. (Eds) Dating Techniques for the Archaeologist. M.I.T. Press, pp. 1–48.Google Scholar

Ralph, E. K. and Michael, H. N. (1974). Twenty-five years of radiocarbon dating. Amer. Scient. 62, 553–60.Google Scholar

Ramsey, C. B. (1995). Radiocarbon calibration and analysis of stratigraphy; the OxCal program. Radiocarbon 37, 425–30.Google Scholar

Reimer, P. J., Bard, E., Bayliss, A. et al. (2013). IntCal13 and Marine13 radiocarbon age calibration curves 0–50,000 years cal BP. Radiocarbon 55, 1869–87.Google Scholar

Reyss, J. L., Yokoyama, Y. and Guichard, F. (1981). Production cross sections of ²⁶Al, ²²Na, ⁷Be from argon and of ¹⁰Be, ⁷Be from nitrogen: implications for the production rates of ²⁶Al and ¹⁰Be in the atmosphere. Earth Planet. Sci. Lett. 53, 203–10.Google Scholar

Roberts, M. L., Burton, J. R., Elder, K. L. et al. (2010). A high-performance ¹⁴C accelerator mass spectrometry system. Radiocarbon 52, 226–35.Google Scholar

Robinson, C., Raisbeck, G. M., Yiou, F., Lehman, B. and Laj, C. (1995). The relationship between ¹⁰Be and geomagnetic field strength records in central North Atlantic sediments during the last 80 ka. Earth Planet. Sci. Lett. 136, 551–7.Google Scholar

Scafetta, N. (2014). Discussion on the spectral coherence between planetary, solar and climate oscillations: a reply to some critiques. Astrophys. Space Sci. 354, 275–99.Google Scholar

Scafetta, N. (2016). High resolution coherence analysis between planetary and climate oscillations. Advances in Space Res. 57, 2121–35.CrossRef Google Scholar

Scafetta, N. and Willson, R. C. (2013). Planetary harmonics in the historical Hungarian aurora record (1523–1960). Planet. Space Sci. 78, 38–44.Google Scholar

Schlesinger, M. E. and Ramankutty, N. (1992). Implications for global warming of intercycle solar irradiance variations. Nature 360, 330–3.Google Scholar

Shackleton, N. J., Duplessy, J.-C., Arnold, M. et al. (1988). Radiocarbon age of last glacial Pacific deep water. Nature 335, 708–11.Google Scholar

Sharma, M. (2002). Variations in solar magnetic activity during the last 200 000 years: is there a Sun–climate connection? Earth Planet. Sci. Lett. 199, 459–72.Google Scholar

Shepard, M. K., Arvidson, R. E., Caffee, M., Finkel, R. and Harris, L. (1995). Cosmogenic exposure ages of basalt flows: Lunar Crater volcanic field, Nevada. Geology 23, 21–4.Google Scholar

Siegenthaler, U. and Sarmiento, J. L. (1993). Atmospheric carbon dioxide and the ocean. Nature 365, 119–25.Google Scholar

Sigmarsson, O., Condomines, M., Morris, J. D. and Harmon, R. S. (1990). Uranium and ¹⁰Be enrichments by fluids in Andean arc magmas. Nature 346, 163–5.Google Scholar

Sikes, E. L., Samson, C. R., Guilderson, T. P. and Howard, W. R. (2000). Old radiocarbon ages in the southwest Pacific Ocean during the last glacial period and deglaciation. Nature 405, 555–9.Google Scholar

Simpson, J. A. (1951). Neutrons produced in the atmosphere by cosmic radiations. Phys. Rev. 83, 1175–88.Google Scholar

Skinner, L. C., Fallon, S., Waelbroeck, C., Michel, E. and Barker, S. (2010). Ventilation of the deep Southern Ocean and deglacial CO₂ rise. Science 328, 1147–51.Google Scholar

Skinner, L., McCave, I. N., Carter, L. et al. (2015). Reduced ventilation and enhanced magnitude of the deep Pacific carbon pool during the last glacial period. Earth Planet. Sci. Lett. 411, 45–52.Google Scholar

Snyder, G., Aldahan, A. and Possnert, G. (2010). Global distribution and long-term fate of anthropogenic ¹²⁹I in marine and surface water reservoirs. Geochem. Geophys. Geosys. 11, Q04010, 1–19.Google Scholar

Snyder, G. T. and Fehn, U. (2002). Origin of iodine in volcanic fluids: ¹²⁹I results from the Central American Volcanic Arc. Geochim. Cosmochim. Acta 66, 3827–38.Google Scholar

Snyder, G. T., Fehn, U. and Goff, F. (2002). Iodine isotope ratios and halide concentrations in fluids of the Satsuma–Iwojima volcano, Japan. Earth,Planets Space 54, 265–73.Google Scholar

Steinhilber, F., Abreu, J. A., Beer, J. et al. (2012). 9,400 years of cosmic radiation and solar activity from ice cores and tree rings. Proc. Nat. Acad. Sci. 109, 5967–71.Google Scholar

Steinhilber, F., Beer, J. and Fröhlich, C. (2009). Total solar irradiance during the Holocene. Geophys. Res. Lett. 36 L19704, 1–5.Google Scholar

Stensland, G. J., Brown, L., Klein, J. and Middleton, R. (1983). Beryllium-10 in rain. EOS 64, 283 (abs.).Google Scholar

Stocker, T. F., Qin, D., Plattner, G. K. et al. Eds.(2014). IPCC, Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press.Google Scholar

Stone, J. O., Allan, G. L., Fifield, L. K. and Cresswell, R. G. (1996). Cosmogenic chlorine-36 from calcium spallation. Geochim. Cosmochim. Acta 60, 679–92.Google Scholar

Stuiver, M. (1961). Variations in radiocarbon concentration and sunspot activity. J. Geophys. Res. 66, 273–6.Google Scholar

Stuiver, M. (1965). Carbon-14 content of 18th- and 19th-century wood: variations correlated with sunspot activity. Science 149, 533–4.Google Scholar

Stuiver, M., Braziunas, T. F., Becker, B. and Kromer, B. (1991). Climatic, solar, oceanic and geomagnetic influences on late-glacial and Holocene atmospheric ¹⁴C/¹²C change. Quat. Res. 35, 1–24.Google Scholar

Stuiver, M. and Pearson, G. W. (1986). High-precision radiocarbon time-scale calibration from the present to 500 BC. Radiocarbon 28, 805–38.Google Scholar

Stuiver, M. and Quay, P. D. (1981). Atmospheric ¹⁴C changes resulting from fossil fuel CO₂ release and cosmic-ray flux variability. Earth Planet. Sci. Lett. 53, 349–62.Google Scholar

Stuiver, M., Quay, P. D. and Ostlund, H. G. (1983). Abyssal water carbon-14 distribution and the age of the world oceans. Science 219, 849–51.Google Scholar

Suess, H. E. (1955). Radiocarbon concentrations in modern wood. Science 122, 415–17.Google Scholar

Suess, H. E. (1965). Secular variations of the cosmic-ray-produced carbon 14 in the atmosphere and their interpretations. J. Geophys. Res. 70, 5937–52.Google Scholar

Suess, H. E. (1970). Bristlecone-pine calibration of the radiocarbon time-scale 5200 B.C. to the present. In: Olsson, I. U. (Ed.) Radiocarbon Variations and Absolute Chronology, Proc. 12th Nobel Symp. Wiley, pp. 303–11.Google Scholar

Suess, H. E. and Strahm, C. (1970). The Neolithic of Auvernier, Switzerland. Antiquity 44, 91–9.Google Scholar

Sun, B. and Bradley, R. S. (2002). Solar influences on cosmic rays and cloud formation: A reassessment. J. Geophys. Res.: Atm. 107 AAC5, 1–12.Google Scholar

Suter, M., Jacob, S. W. A. and Synal, H. A. (2000). Tandem AMS at sub-MeV energies–Status and prospects. Nucl. Instr. Meth. in Phys. Res. B 172, 144–51.Google Scholar

Svensmark, H. and Friis-Christensen, E. (1997). Variation of cosmic ray flux and global cloud coverage – a missing link in solar–climate relationships. J. Atm. Solar–Terrest. Phys. 59, 1225–32.Google Scholar

Tanaka, S. and Inoue, T. (1979). ¹⁰Be dating of North Pacific sediment cores up to 2.5 million years B.P. Earth Planet. Sci. Lett. 45, 181–7.Google Scholar

Tauber, H. (1970). The Scandinavian varve chronology and C-14 dating. In: Olsson, I. U. (Ed.) Radiocarbon Variations and Absolute Chronology, Proc. 12th Nobel Symp. Wiley, pp. 173–96.Google Scholar

Tera, F., Brown, L., Morris, J. et al. (1986). Sediment incorporation in island-arc magmas: inferences from ¹⁰Be. Geochim. Cosmochim. Acta 50, 535–50.Google Scholar

Thellier, E. O. (1941). Sur la verification d'une methode permettant de determiner l'intensite du champ magnetique terrestre dans le passe. Compte Rendu Acad. Sci. Paris 212, 281.Google Scholar

Tobias, S. M. (1996). Grand minimia in nonlinear dynamos. Astron. Astrophys 307, L21–24.Google Scholar

Torgersen, T., Habermehl, M. A., Phillips, F. M. et al. (1991). Chlorine 36 dating of very old groundwater 3. Further studies in the Great Artesian Basin, Australia. Water. Resources. Res. 27, 3201–13.Google Scholar

Turekian, K. K., Cochran, J. K., Krishnaswami, S. et al. (1979). The measurement of ¹⁰Be in manganese nodules using a tandem van de Graaff accelerator. Geophys. Res. Lett. 6, 417–20.Google Scholar

Ullman, W. J. and Aller, R. C. (1980). Dissolved iodine flux from estuarine sediments and implications for the enrichment of iodine at the sediment water interface. Geochim. Cosmochim. Acta 44, 1177–84.Google Scholar

Usoskin, I. G., Solanki, S. K. and Kovaltsov, G. A. (2007). Grand minima and maxima of solar activity: new observational constraints. Astron. Astrophys. 471, 301–9.Google Scholar

Vieira, L. E. A., Solanki, S. K., Krivova, N. A. and Usoskin, I. (2011). Evolution of the solar irradiance during the Holocene. Astron. Astrophys. 531, A6 1–20.Google Scholar

von Blankenburg, F., O'Nions, R. K., Belshaw, N. S., Gibb, A. and Hein, J. R. (1996). Global distribution of beryllium isotopes in deep ocean water as derived from Fe–Mn crusts. Earth Planet. Sci. Lett. 141, 213–26.Google Scholar

Wagner, G., Laj, C., Beer, J. et al. (2001). Reconstruction of the paleoaccumulation rate of central Greenland during the last 75 ka using the cosmogenic radionuclides ³⁶Cl and ¹⁰Be and geomagnetic field intensity data. Earth Planet. Sci. Lett. 193, 515–21.Google Scholar

Wang, L., Ku, T. L., Luo, S., Southon, J. R. and Kusakabe, M. (1996). ²⁶Al–¹⁰Be systematics in deep-sea sediments. Geochim. Cosmochim. Acta 60, 109–19.Google Scholar

Wolfli, W. (1987). Advances in accelerator mass spectrometry. Nucl. Instr. Meth. in Phys. Res. B 29, 1–13.Google Scholar

Yamazaki, T. and Oda, H. (2002). Orbital influence on Earth's magnetic field: 100,000-year periodicity in inclination. Science 295, 2435–8.Google Scholar

Yiou, F., Raisbeck, G. M., Bourles, D., Lorius, C. and Barkov, N. I. (1985). ¹⁰Be in ice at Vostok Antarctica during the last climatic cycle. Nature 316, 616–17.Google Scholar

Yokoyama, Y., Guichard, F., Reyss, J. L., Van, N. H. (1978). Oceanic residence times of dissolved beryllium and aluminium deduced from cosmogenic tracers ¹⁰Be and ²⁶Al. Science 201, 1016–17.Google Scholar

You, C. F., Lee, T. and Li, Y. H. (1989). The partition of Be between soil and water. Chem. Geol. 77, 105–18.Google Scholar

Zreda, M. and Noller, J. S. (1998). Ages of prehistoric earthquakes revealed by cosmogenic chlorine-36 in a bedrock fault scarp at Hebgen Lake. Science 282, 1097–9.Google Scholar

Zreda, M. G., Phillips, F. M., Elmore, D. et al. (1991). Cosmogenic chlorine-36 production rates in terrestrial rocks. Earth Planet. Sci. Lett. 105, 94–109.Google Scholar

Zreda, M. G. and Phillips, F. M. (1995). Surface exposure dating by cosmogenic chlorine-36 accumulation. In: Beck., C. (Ed.) Dating in Exposed and Surface Contexts, University of New Mexico Press, pp. 161–83.Google Scholar

Zreda, M. G., Phillips, F. M. and Elmore, D. (1994). Cosmogenic ³⁶Cl accumulation in unstable landforms 2. Simulations and measurements on eroding moraines. Water Resour. Res. 30, 3127–36.Google Scholar

Book contents

Chapter 14 - Cosmogenic Nuclides

Summary

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive