Abstract
Glacial geologic studies in the Southern Hemisphere (SH) mid-latitudes (40–54°S) indicate renewed glacial activity in southern South America (Patagonia) and New Zealand’s (NZ) South Island starting at ∼7 kyr, the so-called neoglaciation. Available data indicate that neoglacial advances in these regions occurred during a rising trend in atmospheric CO2 and CH4 concentrations, lower-than-present but increasing summer insolation and seasonality contrasts. In this paper we examine the climatological context in which neoglaciations occurred through analysis of the complete Paleoclimate Modelling Inter-comparison Project (PMIP2) database of simulations at 6 kyr for the SH. We observe that the amplitude of the annual insolation cycle in the SH did not change significantly at 6 kyr compared to the pre-industrial values, the largest difference occurring in autumn (MAM, negative anomalies) and spring (SON, positive anomalies). The simulated changes in temperatures over the SH respond to the insolation changes, with a 1–2 month delay over the oceans. This results in a reduced amplitude of the annual cycle of temperature and precipitation over most continental regions, except over Patagonia and NZ, that show a slight increase. In contrast, large-scale circulation features, such as the low and upper level winds and the subtropical anticyclones show an amplified annual cycle, as a direct response to the increased/decreased insolation during the transitional seasons SON/MAM. In the annual mean, there is a small but consistent equatorward shift of the latitude of maximum wind speed of 1–3° over the entire SH, which results in a small increase of wind speed over the South Pacific and Atlantic Oceans north of ∼50°S and a widespread decline south of 50°S. PMIP2 simulations for 6 kyr, indicate that in the annual mean, the SH mid-latitudes were colder, wetter and with stronger winds north of about 50°S. These conditions are consistent with the observed neoglacial advances in the region, as well as with terrestrial paleoclimate records from Patagonia that indicate cooling and a multi-millennial rising trend in Southern Westerly Wind intensity starting at ∼7.8 kyr.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abarzua AM, Villagran C, Moreno PI (2004) Deglacial and postglacial climate history in east-central Isla Grande de Chiloe, southern Chile (43 degrees S). Quat Res 62:49–59
Anderson B, Mackintosh A (2006) Temperature change is the major driver of late-glacial and Holocene glacier fluctuations in New Zealand. Geology 34(2):121–124. doi:10.1130/G22151.1
Anderson B, Mackintosh A, Stumm D, George L, Kerr T, Winter-Billington A, Fitzsimons S (2010) Climate sensitivity of a high-precipitation glacier in New Zealand. J Glaciol 56(195):114–128
Braconnot P, Otto-Bliesner B, Harrison S, Joussaume S, Peterschmitt JY, Abe-Ouchi A, Crucifix M, Driesschaert E, Fichefet Th, Hewitt CD, Kageyama M, Kitoh A, Laine A, Loutre M-F, Marti O, Merkel U, Ramstein G, Valdes P, Weber SL, Yu Y, Zhao Y (2007) Results of PMIP2 coupled simulations of the mid-Holocene and Last Glacial Maximum. Part 1: experiments and large-scale features. Clim Past 3:261–277
Fitzharris BB, Clare GR, Renwick J (2007) Teleconnections between Andean and New Zealand glaciers. Glob Planet Change 59:159–174
Gilli A, Ariztegui D, Anselmetti FS, McKenzie JA, Markgraf V, Hajdas I, McCulloch RD (2005) Mid-Holocene strengthening of the Southern westerlies in South America: sedimentological evidences from Lago Cardiel, Argentina (49°S). Glob Planet Change 49:75–93
Heusser CJ (1993) Late Quaternary forest-steppe contact zone, Isla Grande de Tierra del Fuego, subantarctic South America. Quat Sci Rev 12:169–177
Hooker BL, Fitzharris BB (1999) The correlation between climatic parameters and the retreat and advance of Franz Josef Glacier, New Zealand. Glob Planet Change 22:39–48
Joussaume S, Braconnot P (1997) Sensitivity of Paleoclimate simulation results to season definitions. J Geophys Res 102:1943–1956
Kutzbach JE, Liu Z (1997) Response of the African monsoon to orbital and ocean feedbacks in the Middle Holocene. Science 278:440. doi:10.1126/science.278.5337.440
Lamy F, Hebbelm D, Rohl U, Wefer G (2001) Holocene rainfall variability in southern Chile: a marine record of latitudinal shifts of the southern westerlies. Earth Planet Sci Lett 185:369–382
Liu Z, Harrison SP, Kutzbach J, Otto-Bliesner B (2004) Global monsoons in the mid-Holocene and oceanic feedback. Clim Dyn 22:157–182. doi:10.1007/s00382-003-0372-y
Liu Z, Otto-Bliesner BL, He F, Brady EC, Tomas R, Clark PU, Carlson AE, Lynch-Stieglitz J, Curry W, Brook E, Erickson D, Jacob R, Kutzbach J, Cheng J (2009) Transient simulation of last deglaciation with a new mechanism for Bolling-Allerod warming. Science 325. doi:10.1126/science.1171041
Markgraf V (1993) Paleoenvironments and Paleoclimates in Tierra-Del-Fuego and Southernmost Patagonia, South-America. Palaeogeogr Palaeoclimatol Palaeoecol 102:53–68
Massaferro J, Brooks SJ (2002) Response of chironomids to late quaternary environmental change in the Taitao Peninsula, southern Chile. J Quat Sci 17:101–111
Monnin E, Steig EJ, Siegenthaler U, Kawamura K, Schwander J, Stauffer B, Stocker TF, Morse DL, Barnola JM, Bellier B, Raynaud D, Fischer H (2004) Evidence for substantial accumulation rate variability in Antarctica during the Holocene, through synchronization of CO2 in the Taylor Dome, Dome C and DML ice cores. Earth Planet Sci Lett 224:45–54. doi:10.1016/j.epsl.2004.05.007.228
Moreno PI (2004) Millennial-scale climate variability in northwest Patagonia over the last 15000 yr. J Quat Sci 19:35–47
Moreno PI, Francois JP, Villa-Martinez R, Moy CM (2010) Covariability of the Southern Westerlies and atmospheric CO2 during the Holocene. Geology (in press). doi:10.1130/G30962.1
Oerlemans J, Reichert BK (2000) Relating glacier mass balance to meteorological data by using a seasonal sensitivity characteristic. J Glaciol 46:1–6
Porter SC (2000) Onset of neoglaciation in the Southern Hemisphere. J Quat Sci 15(4):395–408
Rojas M, Moreno P, Kageyama M, Crucifix M, Hewitt C, Abe A, Ohgaito R, Brady E, Hope P (2009) The last glacial maximum in the Southern Hemisphere in PMIP2 simulations. Clim Dyn 32:525–547. doi:10.1007/s00382-008-0421-7
Schaefer JM, Denton GH, Kaplan M, Putnam A, Finkel RC, Barrell DJA, Andersen BG, Schwartz R, Mackintosh A, Chinn T, Schluchter C (2009) High-frequency Holocene glacier fluctuations in New Zealand differ from the Northern Signature. Science:324:622–625
Shulmeister J, Goodwin I, Renwick J, Harle K, Armand L, McGlone MS, Cook E, Dodson J, Hesse PP, Mayewski P, Curran M (2004) The Southern Hemisphere Westerlies in the Australasian sector over the last glacial cycle: a synthesis. Quat Int 118–119:23–53
Wagner S, Widmann M, Jones J, Haberzettl T, Lücke A, Mayr C, Ohlendorf C, Schäbitz F, Zolitschka B (2007) Transient simulations, empirical reconstructions and forcing mechanisms for the mid-Holocene hydrological climate in southern Patagonia. Clim Dyn 29:333–355. doi:10.1007/s00382-007-0229-x
Waldmann N, Ariztegui D, Anselmetti FS, Austin JAJ, Moy CM, Stern C, Recasens C, Dunbar RB (2009) Holocene climatic fluctuations and positioning of the Southern Hemisphere Westerlies in Tierra del Fuego (54°S), Patagonia. J Quat Sci. doi:10.1002/jqs.1263
Whitlock C, Moreno PI, Bartlein PJ (2007) Holocene fire patterns in southern South America: present-day analogues for past periods of high fire activity. Quat Res 68:28–36
Wohlfahrt J, Harrison SP, Braconnot P (2004) Synergistic feedbacks between ocean and vegetation on mid- and high-latitude climates during the mid-Holocene. Clim Dyn 22:223–238. doi:10.1007/s00382-003-0379-4
Acknowledgments
We thank Dr. Bartlein for providing the insolation data from which Fig. 1 was constructed. We acknowledge the international modelling groups for providing their data for analysis, the Laboratoire des Sciences du Climat et de l’Environnement (LSCE) for collecting and archiving the model data. The PMIP2/MOTIF Data Archive is supported by CEA, CNRS, the EU project MOTIF (EVK2-CT-2002-00153) and the Programme National d’Etude de la Dynamique du Climat (PNEDC). The analyses were performed using version mm-dd-yyyy of the database. More information is available on http://www-lsce.cea.fr/pmip/ and http://www-lsce.cea.fr/motif. This investigation was supported by FONDECYT grant # 1090588 and Instituto de Ecología y Biodiversidad (IEB) and Iniciativa Científica Milenio P05002, contract PFB-23.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Rojas, M., Moreno, P.I. Atmospheric circulation changes and neoglacial conditions in the Southern Hemisphere mid-latitudes: insights from PMIP2 simulations at 6 kyr. Clim Dyn 37, 357–375 (2011). https://doi.org/10.1007/s00382-010-0866-3
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00382-010-0866-3