Constraining sources and relative flow rates of bottom waters in the Late Cretaceous Pacific Ocean

Geochemical data suggest that ocean circulation patterns changed over a period of longterm cooling during the last 10 m.y. of the Cretaceous (late Campanian-Maastrichtian). Proposed changes include enhanced deep-water formation in the South Atlantic and/or Indian sectors of the Southern Ocean, initi...

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Bibliographic Details
Published in:Geology (Boulder) 2020-05, Vol.48 (5), p.509-513
Main Authors: Haynes, Shannon J, MacLeod, Kenneth G, Ladant, Jean-Baptiste, Vande Guchte, Andrew, Rostami, Masoud A, Poulsen, Christopher J, Martin, Ellen E
Format: Article
Language:English
Subjects:
bottom currents
C-13/C-12
carbon
Carbon dioxide
chemostratigraphy
climate change
climate effects
Climatology
Computer simulation
Convection
Cooling
cores
Cretaceous
currents
Deep sea
Deep sea drilling
Deep Sea Drilling Project
Deep water
Deep water formation
Deepwater drilling
digital simulation
Drilling
DSDP Site 463
Earth Sciences
Equatorial Pacific
experimental studies
Flow rates
Flow velocity
Geochemistry
Geology
IPOD
isotope ratios
isotopes
Leg 192
Leg 62
marine sediments
Mesozoic
metals
Mid-Pacific Mountains
Nd-144/Nd-143
Neodymium
North Pacific
Northwest Pacific
numerical models
O-18/O-16
Ocean circulation
Ocean circulation patterns
Ocean currents
Ocean Drilling Program
Oceans
ODP Site 1186
Ontong Java Plateau
oxygen
Pacific Ocean
paleo-oceanography
paleoclimatology
Paleogeography
rare earths
Sciences of the Universe
sediments
South Pacific
Southwest Pacific
stable isotopes
Stratigraphy
Upper Cretaceous
Water circulation
West Pacific
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Summary:Geochemical data suggest that ocean circulation patterns changed over a period of longterm cooling during the last 10 m.y. of the Cretaceous (late Campanian-Maastrichtian). Proposed changes include enhanced deep-water formation in the South Atlantic and/or Indian sectors of the Southern Ocean, initiation or enhanced deep-water formation in the North Atlantic, and alternating regions of deep convection in the North and South Pacific. Existing geochemical data do not allow simple confirmation or rejection of any of these scenarios. To test Pacific circulation during the Maastrichtian, we measured neodymium isotopic (εNd) values from four Pacific Deep Sea Drilling Project and Ocean Drilling Program sites and compare results both to Earth system model simulations using Maastrichtian paleogeography and to previous studies. Pacific εNd results consistently show a small negative εNd excursion during a well-documented, ∼1-3 m.y. early Maastrichtian cooling pulse (EMCP) but no other consistent trends across the late Campanian-late Maastrichtian interval (∼10 m.y.). Model results show that different CO2 forcings lead to changes in rates, but not patterns, of circulation. These combined results support the existence of a sustained source region for intermediate and deep waters in the southwestern Pacific throughout the late Campanian-Maastrichtian and indicate that changes in εNd values during the EMCP reflect an increased rate of overturning in the Pacific rather than changes in the source area of Pacific bottom waters.
ISSN:0091-7613
1943-2682
DOI:10.1130/G47197.1