Your search keyword '"Grootes, P. M."' showing total 11 results

1. Peak glacial 14C ventilation ages suggest major draw-down of carbon into the abyssal ocean

Author

Sarnthein, M., Schneider, B., and Grootes, P. M.

Subjects

lcsh:GE1-350, lcsh:Environmental pollution, lcsh:Environmental protection, lcsh:TD172-193.5, lcsh:TD169-171.8, lcsh:Environmental sciences

Abstract

Ice core records demonstrate a glacial–interglacial atmospheric CO2 increase of ~ 100 ppm, while 14C calibration efforts document a strong decrease in atmospheric 14C concentration during this period. A calculated transfer of ~ 530 Gt of 14C-depleted carbon is required to produce the deglacial coeval rise of carbon in the atmosphere and terrestrial biosphere. This amount is usually ascribed to oceanic carbon release, although the actual mechanisms remained elusive, since an adequately old and carbon-enriched deep-ocean reservoir seemed unlikely. Here we present a new, though still fragmentary, ocean-wide Δ14C data set showing that during the Last Glacial Maximum (LGM) and Heinrich Stadial 1 (HS-1) the maximum 14C age difference between ocean deep waters and the atmosphere exceeded the modern values by up to 1500 14C yr, in the extreme reaching 5100 14C yr. Below 2000 m depth the 14C ventilation age of modern ocean waters is directly linked to the concentration of dissolved inorganic carbon (DIC). We propose as a working hypothesis that the modern regression of DIC vs. Δ14C also applies for LGM times, which implies that a mean LGM aging of ~ 600 14C yr corresponded to a global rise of ~ 85–115 μmol DIC kg−1 in the deep ocean. Thus, the prolonged residence time of ocean deep waters may indeed have made it possible to absorb an additional ~ 730–980 Gt DIC, one third of which possibly originated from intermediate waters. We also infer that LGM deep-water O2 dropped to suboxic values of < 10 μmol kg−1 in the Atlantic sector of the Southern Ocean, possibly also in the subpolar North Pacific. The deglacial transfer of the extra-aged, deep-ocean carbon to the atmosphere via the dynamic ocean–atmosphere carbon exchange would be sufficient to account for two trends observed, (1) for the increase in atmospheric CO2 and (2) for the 190‰ drop in atmospheric Δ14C during the so-called HS-1 "Mystery Interval", when atmospheric 14C production rates were largely constant.

Published

2013

2. Rapid response of tree cellulose radiocarbon content to changes in atmospheric 14CO2 concentration

Author

Grootes, P. M., Farwell, G. W., Schmidt, F. H., Leach, D. D., and Stuiver, M.

Abstract

A detailed radial profile for the 14C concentration in tree stem cellulose, covering growth rings for the years 1962–1964, was obtained for a Sitka spruce of the US Pacific Coast using accelerator mass spectrometry. The tree cellulose 14C closely follows atmospheric 14CO2 concentrations, responding to changes with an apparent delay of 5 to 6 weeks. The delay in response is mostly due to the addition of between 13% and 28% of biospheric CO2 to the canopy-air CO2 used by the tree for stem cellulose. Delayed incorporation and the use of stored photosynthate of the previous fall appear less important.DOI: 10.1111/j.1600-0889.1989.tb00131.x

Published

2011

3. Precise chronology of Heinrich-1 meltwater pulses in the Nordic Seas

Author

Sarnthein, Michael, Grootes, P. M., Kuehn, H., and Voelker, Antje H. L.

Subjects

Heinrich events, Cronologia, Oceanografia, Atlântico Norte

Published

2009

4. How relevant is recalcitrance for the stabilization of organic matter in soils?

Author

Marschner, B, Brodowski, S, Dreves, A, Gleixner, G, Gude, A, Grootes, P M, Hamer, U, Heim, A, Jandl, G, Ji, R, Kaiser, K, Kalbitz, K, Kramer, C, Leinweber, P, Rethemeyer, J, Schäffer, A, Schmidt, M W I, Schwark, L, Wiesenberg, G L B, University of Zurich, and Marschner, B

Subjects

10122 Institute of Geography, 1110 Plant Science, eview • stabilization mechanism • 14C age • 13C : 12C ratio • black carbon • DOM • lignin • lipids • SOM fractions • molecular turnover, 910 Geography & travel, 1111 Soil Science

Published

2008

5. Storage and stability of organic matter and fossil carbon in a Luvisol and Phaeozem with continuous maize cropping: A synthesis - Review Article

Author

Flessa, H., Amelung, W., Helfrich, M., Wiesenberg, G. L. B., Gleixner, G., Brodowski, S., Rethemeyer, Janet, Kramer, C., and Grootes, P. M.

Published

2008

6. How relevant is recalcitrance for the stabilization of organic matter in soils? - Review Article

Author

Marschner, B., Brodowski, S., Dreves, A., Gleixner, G., Gude, A., Grootes, P. M., Hamer, U., Heim, A., Jandl, G., Ji, R., Kaiser, K., Kalbitz, K., Kamer, C., Leinweber, P., Rethemeyer, Janet, Schäfer, Angela, Schmidt, Matthias, Schwark, L., and Wiesenberg, G. L. B.

Published

2008

7. A cremated bone intercomparison study

Author

Naysmith, P., Scott, E. M., Cook, G. T., Heinemeier, J., Plicht, J., Strydonck, M., Ramsey, C. B., Grootes, P. M., and Freeman, Spht

Published

2007

8. Radiocarbon analysis of functional-defined and molecular organic matter fractions from agricultural soil profiles

Author

Rethemeyer, Janet, Kramer, C., Gleixner, G., John, B., Yamashita, T., Flessa, H., Andersen, N., Nadeau, M. J., and Grootes, P. M.

Published

2005

9. The Gundestrup cauldron:new scientific and technical investigations

Author

Nielsen, S., Andersen, J. H., Baker, J. A., Christensen, C., Glastrup, J., Grootes, P. M., Hüls, M., Jouttijärvi, A., Larsen, E. B., Madsen, H. B., Müller, K., Nadeau, M. J., Röhrs, S., Stege, H., Stos, Z. A., and Tod Waight

Published

2005

10. Arctic Ocean during the Last Glacial Maximum: Atlantic and polar domains of surface water mass distribution and ice cover

Author

Nørgaard-Pedersen, Niels, Spielhagen, Robert, Erlenkeuser, H., Grootes, P. M., Heinemeier, J., and Knies, J.

Abstract

On the basis of 52 sediment cores, analyzed and dated at high resolution, the paleoceanography and climate of the Last Glacial Maximum (LGM) were reconstructed in detail for the Fram Strait and the eastern and central Arctic Ocean. Sediment composition and stable isotope data suggest three distinct paleoenvironments: (1) a productive region in the eastern to central Fram Strait and along the northern Barents Sea continental margin characterized by Atlantic Water advection, frequent open water conditions, and occasional local meltwater supply and iceberg calving from the Barents Sea Ice Sheet; (2) an intermediate region in the southwestern Eurasian Basin (up to 84–85°N) and the western Fram Strait characterized by subsurface Atlantic Water advection and recirculation, a moderately high planktic productivity, and a perennial ice cover that breaks up only occasionally; and (3) a central Arctic region (north of 85°N in the Eurasian Basin) characterized by a low-salinity surface water layer and a thick ice cover that strongly reduces bioproduction and bulk sedimentation rates. Although the total inflow of Atlantic Water into the Arctic Ocean may have been reduced during the LGM, its impact on ice coverage and halocline structure in the Fram Strait and southwestern Eurasian Basin was strong.

Published

2003

11. IntCal09 and Marine09 radiocarbon age calibration curves, 0 - 50,000 years cal BP

Author

Paula Reimer, Baillie, M. G. L., Bard, E., Bayliss, A., Beck, J. W., Blackwell, P. G., Bronk Ramsey, C., Buck, C. E., Burr, G. S., Edwards, R. L., Friedrich, M., Grootes, P. M., Guilderson, T. P., Hajdas, I., Heaton, T. J., Hogg, A. G., Hughen, K. A., Kaiser, K. F., Kromer, B., Gerry Mccormac, F., Manning, S. W., Reimer, R. W., Richards, D. A., Southon, J. R., Talamo, S., Turney, C. S. M., Plicht, J., and Weyhenmeyer, C. E.

Subjects

Earth and Planetary Sciences(all)

Abstract

The IntCal04 and Marine04 radiocarbon calibration curves have been updated from 12 cal kBP (cal kBP is here defined as thousands of calibrated years before AD 1950), and extended to 50 cal kBP, utilizing newly available data sets that meet the IntCal Working Group criteria for pristine corals and other carbonates and for quantification of uncertainty in both the 14C and calendar timescales as established in 2002. No change was made to the curves from 0-12 cal kBP. The curves were constructed using a Markov chain Monte Carlo (MCMC) implementation of the random walk model used for IntCal04 and Marine04. The new curves were ratified at the 20th International Radiocarbon Conference in June 2009 and are available in the Supplemental Material at www.radiocarbon.org.