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Leg 202 synthesis: Southeast Pacific paleoceangraphy

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Title Leg 202 synthesis: Southeast Pacific paleoceangraphy
Names Tiedemann, Ralf (creator)
Mix, Alan C. (creator)
Date Issued 2007 (iso8601)
Abstract Ocean Drilling Program (ODP) Leg 202 has opened a new window
into understanding late Paleogene and Neogene global environmental
change by providing high-quality sediment sequences from a previously
unsampled region, the eastern South Pacific. Eleven sites (1232–
1242) that record variations on timescales ranging from decades to tens
of millions of years were drilled and investigated on transects of both
depth (489–4072 m) and latitude (41°S–8°N). Building on the shipboard
results presented in the Leg 202 Initial Reports volume, postcruise research
has significantly improved the stratigraphic framework and provided
new insights into climate-related processes, which operate on
different timescales and are relevant to hypotheses concerning the bipolar
“see-saw” climate mechanism, orbitally driven changes in the
continent-ocean-ice-atmosphere system and tectonic processes associated
with the uplift of the Andes, closure of the Central American Seaway,
and major expansions of polar ice sheets.
Stable isotope records and refinements in bio- and magnetostratigraphy
in combination with orbitally tuned cyclostratigraphy significantly
improved the Pleistocene stratigraphy at Sites 1233 and 1234, the Miocene–
Pliocene stratigraphy at Sites 1236, 1237, 1239, and 1241, and the
Oligocene stratigraphy around the late Oligocene climate optimum at
Site 1237. Site 1233 filled a crucial gap in the stratigraphic and paleoceanographic
archive of the South Pacific sector of the Southern
Ocean by providing an outstanding reproducible accelerator mass spectrometry
(AMS) ¹⁴C-dated paleomagnetic record of centennial- and millennial-
scale variability, representing regional variations in
environmental/climatic conditions for the past 70,000 yr. With regard
to the Cenozoic timetable, the continuous and complete sedimentary sequence of Site 1237, spanning the last ~31 m.y., has the potential of
becoming a stratigraphic reference section for the South Pacific. Postcruise
work demonstrated the excellence of this record for producing a
stratigraphic framework that combines the biostratigraphy and terrific
magnetostratigraphy with orbitally tuned stable isotope records.
With respect to the bipolar see-saw hypotheses, Leg 202 studies on
high-resolution records changed the view of the global distribution of
millennial-scale climate change. These studies clearly demonstrate that
millennial-scale climate and biogeochemical systems of the southeast
Pacific and Chile closely align with those recorded in Antarctica and
the southern oceans and that these climate patterns extend to the equatorial
Pacific, either transmitted directly by the eastern boundary current
or indirectly by “the oceanic tunnel” (subsurface transport via
Antarctic Mode or Intermediate Water, Equatorial Undercurrent) injecting
Southern Hemisphere extratropical water masses into the equatorial
upwelling system.
On orbital timescales, most spectacular was the finding that Earth’s
final transition into an “icehouse” climate ~13.9 m.y. ago, the middle
Miocene intensification of Antarctic glaciation, coincided with a striking
transition from obliquity to eccentricity as the drivers of climate
change. Thus, the late Pleistocene 100-k.y. climate cycles are not unique
in Earth’s history, and although the examples from the Miocene and
Pleistocene are both associated with climate cooling, they occur under
significantly different global boundary conditions. This important contribution
from Leg 202 issues a challenge to climatologists to understand
multiple origins of 100-k.y. climate cycles that are now well
documented in the geologic record.
On timescales of millions of years, late Neogene upper ocean temperature
reconstructions in combination with salinity assessments at selected
sites from Leg 202 provide further insights into the
reorganization of ocean-atmosphere couplings that are linked to the
shoaling of the Central American Seaway (CAS), uplift of the Andes,
and Pliocene amplification of polar ice sheet expansion. Regional shoaling
of the thermocline in the low-latitude eastern Pacific from 5.3 to 4.0
Ma most likely resulted from shoaling of the CAS, as suggested by
model experiments. Mixed-layer cooling and freshening in the tropical
northeast Pacific warm pool as well as declining sea-surface temperature
(SST) and increasing biological productivity off Chile parallel intensification
of Northern Hemisphere glaciation from 3.6 to 2.4 Ma. The similarity
of temporal changes in SST, upwelling, and dust flux between the
Benguela and Chile upwelling systems suggests that uplift of the Andes
was probably of secondary importance for generating the observed
changes in the southeast Pacific within the last 6 m.y., as the Benguela
upwelling system was not affected by mountain uplift. The expected atmosphere-
oceanic response of the southeast Pacific to uplift of the
Andes probably played a larger role during the late Miocene, prior to 6
Ma.
A particular scientific challenge of future Leg 202 paleoclimate research
is to better understand the transitions between these different
timescales with respect to couplings between global, regional, and local
processes.
Genre Article
Identifier Tiedemann R., Mix, A. C. (2007).Leg 202 synthesis: southeast Pacific paleoceangraphy. Proceedings of the Ocean Drilling Program, Scientific Results, 202, 1-56.

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