Your search keyword '"Breitenbach, Sebastian F. M."' showing total 2 results

1. Local and Regional Indian Summer Monsoon Precipitation Dynamics During Termination II and the Last Interglacial

Author

Magiera, Matthias, Lechleitner, Franziska A., Erhardt, Andrea M., Hartland, Adam, Kwiecien, Ola, Cheng, Hai, Bradbury, Harold J., Turchyn, Alexandra V., Riechelmann, Sylvia, Edwards, Lawrence, and Breitenbach, Sebastian F. M.

Abstract

To date Indian summer monsoon (ISM) dynamics have been assessed by changes in stalagmite δ18O. However, stalagmite δ18O is influenced by multiple environmental factors (e.g., atmospheric moisture transport, rainfall amount at the study site, and ISM seasonality), precluding simple and clear reconstructions of rainfall amount or variability. This study aims to disentangle these environmental factors by combining δ18O, δ44Ca, and elemental data from a stalagmite covering Termination II and the last interglacial from Mawmluh Cave, NE India, to produce a semiquantitative reconstruction of past ISM rainfall. We interpret δ18O as a mixed signal of rainfall source dynamics and rainfall amount and coupled δ44Ca and X/Ca ratios as indicators of local infiltration rate and prior calcite precipitation in the karst zone. The wettest conditions in our studied interval (135 and 100 kyrs BP; BP = before present, with the present being 1950 CE) occurred during Marine Isotope Stage 5e. Our multiproxy data set suggests a likely change in seasonal distribution of Marine Isotope Stage 5e rainfall compared to the Holocene; the wet season was longer with higher‐than‐modern dry season rainfall. Using the last interglacial as an analogue for future anthropogenic warming, our data suggest a more erratic ISM behavior in a warmer world. This study represents a first multiproxy stalagmite record from the Indian summer monsoon domain covering Termination II and Marine Isotope Stage 5eCombining δ18O, δ44Ca, and elemental data helps to discriminate between rainfall source and amount and local infiltrationThe rainy season during Marine Isotope Stage 5e was wetter, likely with more extreme rainfall events, compared to the Holocene

Published

2019

2. Aerosol forcing of the position of the intertropical convergence zone since ad 1550

Author

Ridley, Harriet E., Asmerom, Yemane, Baldini, James U. L., Breitenbach, Sebastian F. M., Aquino, Valorie V., Prufer, Keith M., Culleton, Brendan J., Polyak, Victor, Lechleitner, Franziska A., Kennett, Douglas J., Zhang, Minghua, Marwan, Norbert, Macpherson, Colin G., Baldini, Lisa M., Xiao, Tingyin, Peterkin, Joanne L., Awe, Jaime, and Haug, Gerald H.

Abstract

The position of the intertropical convergence zone is an important control on the distribution of low-latitude precipitation. Its position is largely controlled by hemisphere temperature contrasts. The release of aerosols by human activities may have resulted in a southward shift of the intertropical convergence zone since the early 1900s (refs , , , , ) by muting the warming of the Northern Hemisphere relative to the Southern Hemisphere over this interval, but this proposed shift remains equivocal. Here we reconstruct monthly rainfall over Belize for the past 456 years from variations in the carbon isotope composition of a well-dated, monthly resolved speleothem. We identify an unprecedented drying trend since ad 1850 that indicates a southward displacement of the intertropical convergence zone. This drying coincides with increasing aerosol emissions in the Northern Hemisphere and also marks a breakdown in the relationship between Northern Hemisphere temperatures and the position of the intertropical convergence zone observed earlier in the record. We also identify nine short-lived drying events since ad 1550 each following a large volcanic eruption in the Northern Hemisphere. We conclude that anthropogenic aerosol emissions have led to a reduction of rainfall in the northern tropics during the twentieth century, and suggest that geographic changes in aerosol emissions should be considered when assessing potential future rainfall shifts in the tropics.

Published

2015