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4. NW Greenland Glaciated Margin: Cenozoic evolution of the northern Greenland Ice Sheet exposed by transect drilling in northeast Baffin Bay.

Author

Knutz, Paul C., Jennings, Anne, and Childress, Laurel B.

Subjects
CENOZOIC Era, CRYOSPHERE, UNDERWATER drilling
Abstract

Elucidating the geologic history of the Greenland Ice Sheet (GrIS) is essential for understanding glacial instability thresholds, identified as major climate system tipping points, and how the cryosphere will respond to anthropogenic greenhouse gas emissions. To address current knowledge gaps in the evolution and variability of the GrIS and its role in Earth's climate system, International Ocean Discovery Program (IODP) Expedition 400 obtained sedimentary records from Sites U1603-U1608 across the northwest Greenland margin into Baffin Bay where thick Cenozoic sedimentary successions can be directly linked to the evolution of the northern GrIS (NGrIS). The strategy of drilling along this transect was to retrieve a composite stratigraphic succession representing the late Cenozoic era from the Oligocene/early Miocene to Holocene. The proposed sites targeted high-accumulation rate deposits associated with contourite drifts and potential interglacial deposits within a trough mouth fan system densely covered by seismic data. The principal objectives were to (1) test if the NGrIS underwent near-complete deglaciations in the Pleistocene and assess the ice sheet's response to changes in orbital cyclicities through the mid-Pleistocene transition; (2) ascertain the timing of the NGrIS expansion and examine a hypothesized linkage between marine heat transport through Baffin Bay and high Arctic warmth during the Pliocene; and (3) provide new understandings of climate-ecosystem conditions in Greenland during the geologic periods with increased atmospheric CO2 compared to preindustrial values, encompassing the last 30 My. The deep time objective was attained by coring at Site U1607 on the inner shelf to 978 meters below seafloor, capturing a succession of mainly Miocene and Oligocene age. The six sites drilled during Expedition 400 resulted in 2299 m of recovered core material, and wireline downhole logging was completed at Sites U1603, U1604, U1607, and U1608. This unique archive will provide the basis for understanding the full range of forcings and feedbacks--oceanic, atmospheric, orbital, and tectonic--that influence the GrIS over a range of timescales, as well as conditions prevailing at the time of glacial inception and deglacial to interglacial periods. We anticipate that the shipboard data and further analytical work on Expedition 400 material can constrain predictive models addressing the GrIS response to global warming and its impending effects on global sea levels. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Contributions of Polycyclic Aromatic Hydrocarbons (PAH) Derived from Angiosperms and Wildfires in Campanian to Paleocene Sediments from High Southern Latitudes

Author

Brassell, Simon C, Doiron, Kelsey, Bijl, Peter, Wagner, Thomas, Herrle, Jens O, Uenzelmann-Neben, Gabriele, Bohaty, Steven M, Childress, Laurel B, Expedition 392 Science Party, Brassell, Simon C, Doiron, Kelsey, Bijl, Peter, Wagner, Thomas, Herrle, Jens O, Uenzelmann-Neben, Gabriele, Bohaty, Steven M, Childress, Laurel B, and Expedition 392 Science Party

Abstract

Core samples recovered from the Transkei Basin (Hole U1581B), offshore South Africa, during IODP Expedition 392 include an expansive record of organic-rich sediments from the Campanian to Paleocene (~74-63 Ma). Investigation of the biomarker composition of this sequence revealed significant amounts of polycyclic aromatic hydrocarbons (PAH) reflecting terrestrial sources of organic matter (OM) coupled with evidence for wildfires. Perylene, derived from diagenetic alteration of terrestrial OM, is the dominant PAH in the Campanian sediments. Other prominent PAH components are tetrahydrochysenes and tetrahydropicenes, which are formed by early-stage diagenetic aromatization, with or without loss of the functionalized A-ring, of triterpenoid lipids. The co-occurrence of their precursor alkenes and ketones afforded further evidence for inputs of angiosperm-derived terrigenous OM, whereas the absence of diterpenoids suggests minimal contributions of terrestrial OM from gymnosperms. The dominance of OM originating from angiosperms throughout this interval suggests that these plants were well-established as the principal vegetation in southern Africa following their expansion during the Late Cretaceous. The presence of coronene in the sedimentary succession indicates that the sources of terrestrial OM also include pyrogenic material because this compound is formed during intense combustion and therefore serves as a sedimentary marker for wildfires. Coronene occurs as a minor PAH component in Campanian samples, but it is a prominent PAH component of the Paleocene samples. It is dominant in the basal Paleocene sample consistent with inputs from global wildfires at the K/Pg boundary, confirming their prevalence at high southern latitudes, whereas the lower proportion of perylene in this interval may reflect a diminished supply of unburnt lignin precursors. Coronene remains a substantive component in later Paleocene samples suggesting the protracted occurrence of wildfires. In a

Published
2023

6. Paleomagnetic and Rock Magnetic Analysis of Sediments and Lavas Obtained on IODP Expedition 392 Agulhas Plateau Cretaceous Climate

Author

Sprain, Courtney J, Dallanave, Edoardo, Guerer, Derya, Kato, Chie, Tessin, Allyson C, Bohaty, Steven M, Uenzelmann-Neben, Gabriele, Childress, Laurel B, Washburn, Sidney, Gaarder, Gabriele, Sprain, Courtney J, Dallanave, Edoardo, Guerer, Derya, Kato, Chie, Tessin, Allyson C, Bohaty, Steven M, Uenzelmann-Neben, Gabriele, Childress, Laurel B, Washburn, Sidney, and Gaarder, Gabriele

Abstract

IODP Expedition 392 to the Agulhas Plateau (AP) recovered sedimentary and igneous sequences from four sites (Sites 392-U1579, 392-U1580, 392-U1581, and 392-U1582) ranging in age from the Late Cretaceous to the Pleistocene. The primary objectives of this expedition were to examine the nature of the AP basement, the opening of oceanic gateways, and the evolution of the climate system through the Cretaceous hothouse and into the Cenozoic. A key to achieving these objectives is the development of high-quality age models for the sedimentary and igneous sequences recovered from each site. Shipboard age models were developed using a combination of biostratigraphic age constraints, in addition to magnetostratigraphy. To improve upon the age model, shore-based paleomagnetic analysis of discrete samples was performed on intervals where polarity could not be confidently determined from shipboard archive half measurements, specifically focused on intervals where refined age models help achieve the Expedition objectives. Rock and environmental magnetic analysis was also performed on select discrete samples to characterize changes in magnetic mineralogy and grain size throughout the sedimentary sequence captured in each hole. Results from rock magnetic experiments help assess the reliability of measured magnetic signals and further can be used to say something about paleoenvironmental conditions. Magnetic minerals are responsive to many environmental changes including changes in sediment source, redox, weathering, and paleooceanographic conditions and can be utilized as a powerful tool for investigating past environments. Magnetic mineralogic changes will be connected to results from pore water geochemistry and astronomical tuning to help further understand the processes behind the observed changes. Here, we will present on the updated magnetostratigraphy and preliminary rock and environmental magnetic analyses.

Published
2023

7. Seafloor weathering of Agulhas Plateau Large Igneous Province volcaniclastics as a driver of ocean chemistry

Author

Tessin, Allyson, McManus, James, Penman, Donald, Uenzelmann-Neben, Gabriele, Burkett, Ashley, Bohaty, Steven M, Childress, Laurel B, Expedition 392 scientists, Tessin, Allyson, McManus, James, Penman, Donald, Uenzelmann-Neben, Gabriele, Burkett, Ashley, Bohaty, Steven M, Childress, Laurel B, and Expedition 392 scientists

Abstract

Seafloor weathering of Agulhas Plateau Large Igneous Province volcaniclastics as a driver of ocean chemistry

Published
2023

8. Core-Log -Seismic Integration for the Cretaceous to Oligocene sequence in the African-Southern Ocean gateway: First results from the Agulhas Plateau (IODP Sites U1579 and U1580)

Author

Uenzelmann-Neben, Gabriele, Gruetzner, Jens, Bohaty, Steven M, Childress, Laurel B, Expedition 392 Scientists, Uenzelmann-Neben, Gabriele, Gruetzner, Jens, Bohaty, Steven M, Childress, Laurel B, and Expedition 392 Scientists

Abstract

Climate models have identified significant geography-related Cenozoic cooling arising from the opening of Southern Ocean gateways (e.g., Sauermilch et al., 2021). For example, a gradual strengthening of the Antarctic Circumpolar Current (ACC) has been proposed as the primary cause of cooler deep ocean temperatures associated with the transition from the Cretaceous "Supergreenhouse" to the Oligocene icehouse (e.g., Sijp et al., 2014). IODP Expedition 392 'Agulhas Plateau Cretaceous Climate' drilled four sites in the African-Southern Ocean gateway in 2022 to significantly advance understanding of how temperatures, ocean circulation, and sedimentation patterns evolved as CO2 levels rose and fell and Gondwana broke up (Uenzelmann-Neben et al., 2022). Prior to Exp 392, seismostratigraphic models developed for the African-Southern Ocean gateway relied solely on age data from remote drilling sites and information from piston cores, gravity cores, and dredge samples. As a result, a high level of uncertainty had to be assumed for reflector age information, particularly for the sparsely sampled pre-Miocene sedimentary column. We here present preliminary findings from a revised seismostratigraphy based on core-log-seismic integration at Sites U1579 (central Agulhas Plateau) and U1580 (southern Agulhas Plateau), both of which are located at the heart of the African-Southern Ocean gateway. Core density and velocity data were edited, corrected to in-situ conditions, and combined with downhole logging data. Synthetic seismograms provide an accurate traveltime to depth conversion and show an excellent correlation of drilling results with the site survey seismic field records. A first correlation of the seismic reflection data with the preliminary shipboard bio- and magnetostratigraphy reveals that the published seismostratigraphic models are erroneous and need revisions, for example, a reflector interpreted to represent a lower Eocene sea level highstand on the Agulhas Plateau has

Published
2023

9. Evolutionary Developments in Alkenones from the Campanian to Paleocene Recorded in Sediments from the Transkei Basin (IODP Site U1581)

Author

Doiron, Klesey, Brassell, Simon C, Bijl, Peter, Wagner, Tom, Herrle, Jens O, Uenzelmann-Neben, Gabriele, Bohaty, Steven M, Childress, Laurel B, Expedition 392 Science Party, Doiron, Klesey, Brassell, Simon C, Bijl, Peter, Wagner, Tom, Herrle, Jens O, Uenzelmann-Neben, Gabriele, Bohaty, Steven M, Childress, Laurel B, and Expedition 392 Science Party

Abstract

Campanian to Paleocene organic-rich sediments (~74-60 Ma) recovered from the Transkei Basin (Hole U1581B), offshore South Africa, during IODP Expedition 392 contain suites of C37-C40 alkenones derived from haptophyte algae that extend the temporal continuity of their occurrences and expand their paleogeographic range to high southern latitudes (~58°S) during this time interval. Alkenone profiles are broadly similar throughout the stratigraphic section with the similarity between Maastrichtian and Danian samples indicating a conformity in biosynthetic pathways across the K/Pg boundary. Thus, the source haptophytes for alkenones survived and subsequently recovered after the extinction event, consistent with temporal trends for assemblages of calcareous nannoplankton from the southern hemisphere. The lineages of specific alkenones record evolutionary developments in their biosynthetic pathways. The occurrence of a methyl C39:2 alkenone in the Paleocene and both methyl and ethyl C38 and C39 alkenones in the Campanian extends the range of occurrence of alkenone with carbonyl groups at multiple positions, and the required duality in their biosynthetic pathways. The dominance of the C40 alkadien-3-one in several samples contrasts with its scarcity in Neogene marine sediments and presence among extant haptophytes. C40 alkenones are prevalent constituents of coastal and lacustrine species in phylogenic Group II, notably Isochrysis, but have only once been reported in marine species from phylogenic Group III. The sporadic prominence of C40 alkenones prior to the early Eocene seems to reflect a broader suite of active biosynthetic pathways than those expressed by extant marine haptophytes. Thus, Cretaceous through Paleocene marine sediments may reflect alkenone contributions from both Isochrysidaceae (Group II) and Noelaerhabdaceae (Group III) following their divergence in the Early Cretaceous. The accompanying C40:3 alkenone contrasts with the absence of other alkatrienones p

Published
2023

10. A source-to-sink perspective of the Waipaoa River margin

Author

Kuehl, Steven A., Alexander, Clark R., Blair, Neal E., Harris, Courtney K., Marsaglia, Kathleen M., Ogston, Andrea S., Orpin, Alan R., Roering, Joshua J., Bever, Aaron J., Bilderback, Eric L., Carter, Lionel, Cerovski-Darriau, Corina, Childress, Laurel B., Reide Corbett, D., Hale, Richard P., Leithold, Elana L., Litchfield, Nicola, Moriarty, Julia M., Page, Mike J., Pierce, Lila E.R., Upton, Phaedra, and Walsh, John P.

Published
2016
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11. Links between spatially heterogeneous pore water geochemistry, fluid migration, and methane hydrate near a seafloor mound venting structure on the south Chilean Margin (41°S)

Author

Clementi, Vincent J, primary, Rosenthal, Yair, additional, Bova, Samantha Claudia, additional, Wright, James, additional, Thomas, Elizabeth K., additional, Mortlock, Richard Andrew, additional, Cowling, Owen C, additional, Godfrey, Linda, additional, and Childress, Laurel B, additional

Published
2022
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12. Agulhas Plateau Cretaceous Climate: drilling the Agulhas Plateau and Transkei Basin to reconstruct the Cretaceous–Paleogene tectonic and climatic evolution of the Southern Ocean basin

Author

Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., the Expedition 392 Scientists, Marine Palynology, and Marine palynology and palaeoceanography

Subjects
Earth Connections, International Ocean Discovery Program, Expedition 392, Climate and Ocean change, Site U1579, Site U15182, Site U15181, Agulhas Plateau Cretaceous Climate, Site U1580, Oceanography, IODP, JOIDES Resolution
Abstract

During International Ocean Discovery Program Expedition 392, three sites were drilled on the Agulhas Plateau and one site was drilled in the Transkei Basin in the Southwest Indian Ocean. This region was positioned at paleolatitudes of ~53°–61°S during the Late Cretaceous (van Hinsbergen et al., 2015) (100–66 Ma) and within the new and evolving gateway between the South Atlantic, Southern Ocean, and southern Indian Ocean basins. Recovery of basement rocks and sedimentary sequences from the Agulhas Plateau sites and a thick sedimentary sequence in the Transkei Basin provides a wealth of new data to (1) determine the nature and origin of the Agulhas Plateau; (2) significantly advance the understanding of how Cretaceous temperatures, ocean circulation, and sedimentation patterns evolved as CO2 levels rose and fell and the breakup of Gondwana progressed; (3) document long-term paleoceanographic variability through the Late Cretaceous and Paleogene; and (4) investigate geochemical interactions between igneous rocks, sediments, and pore waters through the life cycle of a large igneous province (LIP). Importantly, postcruise analysis of Expedition 392 drill cores will allow testing of competing hypotheses concerning Agulhas Plateau LIP formation and the role of deep ocean circulation changes through southern gateways in controlling Late Cretaceous–early Paleogene climate evolution.

Published
2022

13. Well-preserved calcareous nannofossils across the Paleocene–Eocene Thermal Maximum, International Ocean Discovery Program (IODP) Site U1580, central Agulhas Plateau, southwestern Indian Ocean

Author

Kulhanek, Denise K., Archontikis, Odysseas A., Herrle, Jens O., Penman, Donald E., Bohaty, Steven M., Westerhold, Thomas, Burkett, Ashley M., Sprain, Courtney J., Batenburg, Sietkse J., Uenzelmann-Neben, Gabriele, Childress, Laurel B., Kulhanek, Denise K., Archontikis, Odysseas A., Herrle, Jens O., Penman, Donald E., Bohaty, Steven M., Westerhold, Thomas, Burkett, Ashley M., Sprain, Courtney J., Batenburg, Sietkse J., Uenzelmann-Neben, Gabriele, and Childress, Laurel B.

Abstract

The Paleocene-Eocene Thermal Maximum (PETM) was an abrupt and extreme warming event associated with rapid input of light carbon into the ocean-atmosphere system. The carbon cycle perturbations during the PETM caused significant changes to marine plankton, including extinction of some benthic foraminifers and the appearance of malformed calcareous nannoplankton, possibly related to ocean acidification during the event. The PETM is now considered a potential analog for the effects of anthropogenic climate change due to its rapid onset; thus, study of PETM records offers an opportunity to better understand the potential effects of rapid climate change on marine phytoplankton communities. Here we present calcareous nannofossil assemblage data across a newly recovered PETM section from International Ocean Discovery Program (IODP) Site U1580, drilled on the central Agulhas Plateau during IODP Expedition 392 in early 2022. Present water depth at this site is 2560 m and it sits at 40° 47.15’S, although the site has moved progressively northward since the Agulhas Plateau formed in the mid-Cretaceous, when the site was located about 20° further south. The PETM interval was identified during the expedition by a change in sediment color, increase in magnetic susceptibility, and calcareous nannofossil assemblages. Low-resolution bulk 13C measurements conducted following the expedition confirm a negative isotope excursion and decrease in calcium carbonate content across the interval. The shipboard age model based on nannofossil and planktonic foraminifer biostratigraphy, together with magnetostratigraphy, suggests relatively high sedimentation rates (~2.5 cm/kyr). Nannofossil assemblages are quite well preserved, with PETM-specific taxa present including Rhomboaster calcitrapa, Rhomboaster cuspis, Rhomboaster bramlettei, Discoaster araneus, and Discoaster acutus. Initial qualitative analyses indicate Zygrhablithus bijugatus is particularly abundant within the PETM interval, wher

Published
2022

14. Cretaceous–Paleogene calcareous nannofossils from International Ocean Discovery Program Expedition 392 to the Agulhas Plateau, Southwest Indian Ocean

Author

Kulhanek, Denise K., Archontikis, Odysseas A., Herrle, Jens O., Bijl, Peter K, Burkett, Ashley M., Coenen, Jason J., Dallanave, Edoardo, Sprain, Courtney J., Batenburg, Sietkse J., Westerhold, Thomas, Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Kulhanek, Denise K., Archontikis, Odysseas A., Herrle, Jens O., Bijl, Peter K, Burkett, Ashley M., Coenen, Jason J., Dallanave, Edoardo, Sprain, Courtney J., Batenburg, Sietkse J., Westerhold, Thomas, Uenzelmann-Neben, Gabriele, Bohaty, Steven M., and Childress, Laurel B.

Abstract

International Ocean Discovery Program (IODP) Expedition 392 cored three sites on the Agulhas Plateau and one site in the Transkei Basin to address questions regarding the origin and timing of emplacement of Agulhas Plateau, as well as examine Southern Ocean climate history and opening of oceanic gateways from the Cretaceous through the Paleogene. Age models for the sites rely primarily on calcareous nannofossils and magnetostratigraphy, with dinoflagellates providing key events for some intervals, and additional contributions from planktonic foraminifers and diatoms. Site U1579, located in a basin on southern the central Agulhas Plateau, records a nearly continuous section dated to the Santonian to earliest Miocene. Dinoflagellates provide age control for the zeolitic sandstone and siltstone with glauconite at the base of the cored section. Above this, nannofossils are common to abundant and moderately preserved in upper Santonian to Maastrichtian calcareous chalks and the assemblages show Southern Ocean affinities. Paleogene nannofossils are abundant and moderately to well preserved. Sedimentation rates were lowest in the Eocene, which includes either condensed intervals or hiatuses. Nannofossils are well preserved in the Oligocene and assemblages consist of primarily mid-latitude species with occasional incursions of cold-water taxa. Site U1580 is also located on the southern Agulhas Plateau adjacent to a basement high. This site records several unconformities, and the lowermost part of the cored interval is interspersed with basalt layers interpreted as sills. The oldest sediment is likely uppermost Cenomanian in age. Overlying the shallowest basalt is Coniacian–Santonian silt- and sandstone with varying proportions of zeolites, glauconite, and carbonate. Sedimentation rates were very high (~10 cm/ky) during this time. Much of the early Campanian and mid-Maastrichtian is missing at this site. Paleocene nannofossils are moderately well preserved and suggest a cont

Published
2022

15. Agulhas Plateau Cretaceous Climate: drilling the Agulhas Plateau and Transkei Basin to reconstruct the Cretaceous–Paleogene tectonic and climatic evolution of the Southern Ocean basin

Author

Marine Palynology, Marine palynology and palaeoceanography, Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., the Expedition 392 Scientists, Marine Palynology, Marine palynology and palaeoceanography, Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., and the Expedition 392 Scientists

Published
2022

16. Two months at sea on the Joides Resolution and over 2 km of seafloor core from the southern South Africa sheds light on regional climate history

Author

Cawthra, Hayley C., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Cawthra, Hayley C., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., and Childress, Laurel B.

Abstract

This presentation gives an account of the International Ocean Discovery Program (IODP) expedition 392 [Agulhas Plateau Cretaceous Climate: drilling the Agulhas Plateau and Transkei Basin to reconstruct the Cretaceous–Paleogene tectonic and climatic evolution of the Southern Ocean basin] which took place from February to April 2022. Four geological sites were drilled on the seafloor of the Agulhas Plateau and the Transkei Basin (Figure 1). A total of 28 scientists from sailed on the Joides Resolution vessel and the deepest hole drilled of four reached 994 m below the seafloor, in over 4500 m of water. The overarching objectives of Expedition 392’s recovery of rocks and sedimentary sequences were aimed at: (1) determining the nature and origin of the Agulhas Plateau; (2) advancing the understanding of how Cretaceous temperatures, ocean circulation, and sedimentation patterns evolved as CO2 levels rose and fell and the breakup of Gondwana progressed; (3) documenting long-term palaeoceanographic variability through the Late Cretaceous and Paleogene; and (4) investigating geochemical interactions between igneous rocks, sediments, and pore waters through the life cycle of a large igneous province.

Published
2022

17. Preliminary assessment of biomarkers in sediments from the Transkei Basin (IODP Site U1581)

Author

Doiron, Kelsey E., Wagner, Thomas, Bijl, Peter K, Herrle, Jens O., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Brassel, Simon, Doiron, Kelsey E., Wagner, Thomas, Bijl, Peter K, Herrle, Jens O., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., and Brassel, Simon

Abstract

A series of organic-rich sedimentary sequences that span the Paleocene through the Campanian was recovered from the Transkei Basin during IODP Expedition 392. Preliminary analyses of their organic geochemistry reveals suites of biomarkers that reflect diverse contributions of organic matter from both marine and terrestrial sources. The characteristics of the organic matter (OM) for a range of samples have been determined by shipboard and shore-based analyses that include evaluation of OM type and maturity by Rock-Eval pyrolysis, isotopic compositions of OM and the distributions of biomarkers including GDGTs. Samples from both the Paleocene and Campanian contain series of C37 to C40 diunsaturated alkenones, including the earliest record of C38 alkadien-2-ones and C39 alkadien-3-ones [1]. A sequence of Campanian samples also reveal an abundance of C28 sterenes and steryl ethers potentially indicative of upwelling conditions [2]. Polyaromatic hydrocarbons, including coronene, are present throughout the sequence likely reflecting inputs of OM associated with paleofires [3]. Variations in the abundance of organosulfur compounds [4,5] may afford evidence for temporal changes in redox conditions within the Transkei Basin during the Campanian. These initial results provide evidence that biomarker profiling will facilitate determination of the sources of OM throughout Late Cretaceous and Paleocene and the paleoenvironmental conditions of its deposition. [1] Brassell, 2014; [2] Brassell, 2009; [3] Finkelstein et al., 2005; [4] Valisolalao et al., 1984; [5] Brassell et al., 1986

Published
2022

18. Science in Seventeen Syllables: 3.9.2 Haiku

Author

Yakutchik, Maryalice, Cotterill, Carol, Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Yakutchik, Maryalice, Cotterill, Carol, Uenzelmann-Neben, Gabriele, Bohaty, Steven M., and Childress, Laurel B.

Abstract

3.9.2. haiku captures scientific exploration and discovery as it took place in remote locales, far from the public eye. It invites audiences of all ages to engage with cores from the privileged point-of-view of researchers who were the first to see, smell and touch material from deep under the ocean floor; who, after watching the cores be split open, spent hours analyzing each centimeter. Their poems, and especially their readings of them, reveal not only the cores but also the scientists as they experience anticipation, frustration, awe, excitement and wonder. It turns out that haiku is an especially relevant way to package stories from cores of mud and rock from the Cretaceous period, which was the focus of IODP Expedition 392 to the Agulhas Plateau. An ancient poetic form consisting of 17 syllables in three lines (5-7-5), haiku compactly and powerfully captures moments of time . . . moments that, on the surface, may appear unremarkable—a frog jumping. Moments that resonate with the deep truths that emerge from paying close attention to the natural world. When introduced to the concept of 3.9.2 haiku, more than one brilliant researcher balked: “I’m no good at this. . . I can’t write poetry.” During several writing workshops conducted during the expedition, scientists began to recognize haiku as the linguistic equivalent to cores they were studying. They delighted that a dozen (or fewer) precisely packaged words could align so closely with the cores precisely drilled from the Agulhas Plateau. Each individual haiku is a gem. Strung together, they are a trove of impressions that span millennia.

Published
2022

19. Initial results of IODP Expedition 392: Agulhas Plateau Cretaceous Climate

Author

Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., and Childress, Laurel B.

Abstract

International Ocean Discovery Program Expedition 392 drilled three sites on the Agulhas Plateau and one site in the Transkei Basin in the Southwest Indian Ocean in Ferb-March 2022 (Fig. 1). This region was positioned at paleolatitudes of ~53°–61°S during the Late Cretaceous (van Hinsbergen et al., 2015), within a new and evolving oceanic gateway between the South Atlantic, Southern Ocean, and southern Indian Ocean basins. Sedimentary and basement sequences were successfully recovered from the Agulhas Plateau sites U1579, U1580, and U1582, and a thick sedimentary sequence was recovered in the Transkei Basin at Site U1581 (Fig. 2). Drillcores from these four sites provide a wealth of new data to (1) determine the nature, origin, and bathymetric evolution of the Agulhas Plateau; (2) significantly advance the understanding of how Cretaceous temperatures, ocean circulation, and sedimentation patterns evolved as CO2 levels rose and fell and the breakup of Gondwana progressed; (3) document long- and short-term paleoceanographic variability through the Late Cretaceous and Paleogene; and (4) investigate geochemical interactions between igneous rocks, sediments, and pore waters through the life cycle of the Agulhas Plateau large igneous province (LIP). Importantly, postcruise analysis of Expedition 392 drill cores will allow testing of competing hypotheses concerning Agulhas Plateau LIP formation and the role of deep ocean circulation changes through southern gateways in influencing Late Cretaceous–Paleogene climate evolution.

Published
2022

20. Preliminary Assessment of Organic Geochemistry in Sediments from the Transkei Basin (IODP Site U1581)

Author

Doiron, Kelsey E., Wagner, Thomas, Bijl, Peter K, Herrle, Jens O., Coenen, Jason J., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Brassell, Simon, Doiron, Kelsey E., Wagner, Thomas, Bijl, Peter K, Herrle, Jens O., Coenen, Jason J., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., and Brassell, Simon

Abstract

A series of organic-rich sedimentary sequences that span the Paleocene through the Campanian was recovered from the Transkei Basin during IODP Expedition 392. Preliminary analyses of their organic geochemistry reveals suites of biomarkers that reflect diverse contributions of organic matter from both marine and terrestrial sources. The characteristics of the organic matter (OM) for a range of samples have been determined by shipboard and shore-based analyses that include evaluation of OM type and maturity by Rock-Eval pyrolysis, isotopic compositions of OM, and the distributions of aliphatic and aromatic biomarkers. Samples from both the Paleocene and Campanian contain series of C37 to C40 diunsaturated alkenones, including the earliest record of C38 alkadien-2-ones and C39 alkadien-3-ones [1]. Samples from a section of the Campanian (~72.5 Ma) reveal an abundance of C28 steradienes and steryl ethers potentially indicative of upwelling conditions [2]. Polyaromatic hydrocarbons within the sequence include compounds that reflect inputs of OM derived from angiosperms and paleofires [3,4]. Dominant hopanoids in the samples include -homohopane, hop-17(21)-ene, and 29-norhop-17(21)-ene, accompanied by fernenes [5], a C35 hopanoid thiophene [6] and also dammarenes [7] in Paleocene samples. These initial results provide evidence that biomarker profiling will facilitate determination of the sources of OM from the Late Cretaceous to the Paleocene in the Transkei Basin and paleoenvironmental conditions of deposition.

Published
2022

21. The origin of the Agulhas Plateau at the African-Southern Ocean gateway: Planned research on igneous rocks from Exp. 392

Author

Geldmacher, Joerg, Davidson, Peter C, Liu, Jia, Ichiyama, Yuji, Hoernle, Kaj, Uenzelmann-Neben, Gabriele, Bohaty, Steven M, Childress, Laurel B, Geldmacher, Joerg, Davidson, Peter C, Liu, Jia, Ichiyama, Yuji, Hoernle, Kaj, Uenzelmann-Neben, Gabriele, Bohaty, Steven M, and Childress, Laurel B

Abstract

The opening of the Southern Ocean gateways has been debated as a key element in the emergence of the Antarctic Circumpolar Current (ACC), crucial for the onset of global Cenozoic cooling (e.g., Sijp et al., 2014, Glob. Planet. Change 119; Voigt et al., 2013, EPSL 369/370). South of Africa, the opening was associated with the formation of several large igneous provinces (LIPs) including the Mozambique Ridge, Agulhas Plateau and the smaller Northeast Georgia Rise and Maud Rise. Plate tectonic reconstructions imply that the latter two were once part of the much greater Agulhas Plateau and were separated by subsequent rifting (Parsaglia et al., 2008, Geophys. J. Int. 174). It is debated whether and to what extent the emplacement of these large volcanic features obstructed the exchange of water masses between the Atlantic and the Indian Ocean thereby delaying the onset of the ACC. The Agulhas Plateau was drilled during recent IODP Expedition 392 (Uenzelmann-Neben, Bohaty, Childress, et al., IODP Exp. 392 Preliminary Report, 2022, in press). Igneous rocks were recovered at two sites on the southern part of the plateau (Sites U1579, U1580) and at one site near its northern edge (U1582). Preliminary (shipboard) data indicate that all sites returned tholeiitic basalts, formed by low pressure (shallow magma chamber) fractionation of mainly olivine and plagioclase (as typical for mid-ocean ridge basalts and many LIP lavas). 40Ar/39Ar dating will help to answer fundamental questions regarding the emplacement age of the plateau and its temporal-spatial evolution. Geochemical investigations of the recovered rocks will reveal the nature and source of the magmatism. The proposed project will focus on the determination of radiogenic (Sr, Nd, Hf, Pb) isotope compositions to further constrain the magma source composition for comparison with other regional and global LIP magmatism. In particular, we want to address the open question whether the Agulhas Plateau, Northeast Georgia Rise a

Published
2022

22. Expedition 392 Preliminary Report: Agulhas Plateau Cretaceous Climate

Author

Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Uenzelmann-Neben, Gabriele, Bohaty, Steven M., and Childress, Laurel B.

Abstract

The long-term climate transition from the Cretaceous greenhouse to the late Paleogene icehouse provides an opportunity to study changes in Earth system dynamics associated with large changes in global temperature and atmospheric CO2 levels. Elevated CO2 levels during the mid-Cretaceous supergreenhouse interval (~95–80 Ma) resulted in low meridional temperature gradients, and oceanic deposition during this time was punctuated by widespread episodes of severe anoxia termed oceanic anoxic events, resulting in enhanced burial of organic carbon in conjunction with transient carbon isotope and temperature excursions. The prolonged interval of mid-Cretaceous warmth and subsequent Late Cretaceous–Paleogene climate trends, as well as intervening short-lived climate excursions, are poorly documented in the southern high latitudes. International Ocean Discovery Program (IODP) Expedition 392 aims to drill five sites in the southwest Indian Ocean on the Agulhas Plateau and in the Transkei Basin, positioned at paleolatitudes of 65°–58°S during the Late Cretaceous (100–66 Ma) and in the new and evolving gateway between the South Atlantic, Southern Ocean, and southern Indian Ocean basins. Recovery of basement rocks and expanded sedimentary sequences from the Agulhas Plateau and Transkei Basin will provide a wealth of new data to (i) determine the nature and origin of the Agulhas Plateau and (ii) significantly advance the understanding of how Cretaceous temperatures, ocean circulation, and sedimentation patterns evolved as CO2 levels rose and fell and the breakup of Gondwana progressed. Importantly, Expedition 392 drilling will test competing hypotheses concerning Agulhas Plateau large igneous province formation and the role of deep ocean circulation changes through southern gateways in controlling Late Cretaceous–Paleogene climate evolution.

Published
2022

23. Expedition 392 Preliminary Report Agulhas Plateau Cretaceous Climate: drilling the Agulhas Plateau and Transkei Basin to reconstruct the Cretaceous–Paleogene tectonic and climatic evolution of the Southern Ocean basin, 5 February–7 April 2022

Author

Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Archontikis, Odysseas A., Batenburg, Sietske J., Bijl, Peter K., Burkett, Ashley M., Chanda, Pratyusha, Coenen, Jason J., Dallanave, Edoardo, Davidson, Peter C., Doiron, Kelsey E., Geldmacher, Jörg, Gürer, Derya, Haynes, Shannon J., Herrle, Jens O., Ichiyama, Yuji, Jana, Debadrita, Jones, Matthew M., Kato, Chie, Kulhanek, Denise K., Li, Juan, Liu, Jia, McManus, James, Minakov, Alexander N., Penman, Donald E., Sprain, Courtney J., Tessin, Allyson C., Wagner, Thomas, Westerhold, Thomas, Uenzelmann-Neben, Gabriele, Bohaty, Steven M., Childress, Laurel B., Archontikis, Odysseas A., Batenburg, Sietske J., Bijl, Peter K., Burkett, Ashley M., Chanda, Pratyusha, Coenen, Jason J., Dallanave, Edoardo, Davidson, Peter C., Doiron, Kelsey E., Geldmacher, Jörg, Gürer, Derya, Haynes, Shannon J., Herrle, Jens O., Ichiyama, Yuji, Jana, Debadrita, Jones, Matthew M., Kato, Chie, Kulhanek, Denise K., Li, Juan, Liu, Jia, McManus, James, Minakov, Alexander N., Penman, Donald E., Sprain, Courtney J., Tessin, Allyson C., Wagner, Thomas, and Westerhold, Thomas

Published
2022
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24. The Sediment Green-Blue Color Ratio as a Proxy for Biogenic Silica Productivity Along the Chilean Margin

Author

Li, Chen, Clementi, Vincent J., Bova, Samantha C, Rosenthal, Yair, Childress, Laurel B., Wright, James D., Jian, Zhimin, Aiello, Ivano W., Avila, Alejandro, Biggs, William, Charles, Christopher D., Cheung, Anson H., deLong, Kimberly, Dove, Isabel A., Du, Xiaojing, Estes, Emily R., Fuentes, Ursula, García-Lasanta, Cristina, Goldstein, Steven L., Golub, Anna, Hagemann, Julia Rieke, Hatfield, Robert G, Haynes, Laura L., Hess, Anya V., Irvali, Nil, Kiro, Yael, Monteagudo, Minda M., Lambert, Jonathan E., Longo, William M., McGrath, Sarah, Riechelson, Hailey, Robinson, Rebecca S., Sarao, John, Sproson, Adam D., Taylor, Shawn, Yokoyama, Yusuke, and Yu, Siyao M.

Subjects
Geophysics, Geochemistry and Petrology
Abstract

Sediment cores recently collected from the Chilean Margin during D/V JOIDES Resolution Expedition 379T (JR100) document variability in shipboard-generated records of the green/blue (G/B) ratio. These changes show a strong coherence with benthic foraminiferal δ18O, Antarctic ice core records, and sediment lithology (e.g., higher diatom abundances in greener sediment intervals), suggesting a climate-related control on the G/B. Here, we test the utility of G/B as a proxy for diatom productivity at Sites J1002 and J1007 by calibrating G/B to measured biogenic opal. Strong exponential correlations between measured opal% and the G/B were found at both sites. We use the empirical regressions to generate high-resolution records of opal contents (opal%) on the Chilean Margin. Higher productivity tends to result in more reducing sedimentary conditions. Redox-sensitive sedimentary U/Th generally co-varies with the reconstructed opal% at both sites, supporting the association between sediment color, sedimentary U/Th, and productivity. Lastly, we calculated opal mass accumulation rate (MAR) at Site J1007 over the last ∼150,000 years. The G/B-derived opal MAR record from Site J1007 largely tracks existing records derived from traditional wet-alkaline digestion from the south and eastern equatorial Pacific (EEP) Ocean, with a common opal flux peak at ∼50 ka suggesting that increased diatom productivity in the EEP was likely driven by enhanced nutrient supply from the Southern Ocean rather than dust inputs as previously suggested. Collectively, our results identify the G/B ratio as a useful tool with the potential to generate reliable, high-resolution paleoceanographic records that circumvent the traditionally laborious methodology. publishedVersion

Published
2022

26. South Pacific Paleogene Climate

Author

Thomas, Deborah J., Röhl, Ursula, Childress, Laurel B., Anagnostou, Eleni, Ausin, Blanca, Borba Dias, Bruna, Boscolo Galazzo, Flavia, Brzelinski, Swaantje, Dunley, Ann, George, Simon, Haynes, Laura, Ingrid, Hendy, Jones, Heather, Khanolkar, Sonal, Kitch, Gabriella, Lee, Hojun, Sheward, Rosie, Sibert, Elizabeth, Tanaka, Erika, Wilkens, Roy, Yasukawa, Kazutaka, Yuan, Wei, Zhang, Qiang, Drury, Anna-Joy, and Hollis, Chris

Abstract

International Ocean Discovery Program (IODP) Expedition 378 was designed to recover the first comprehensive set of Paleogene sedimentary sections from a transect of sites strategically positioned in the South Pacific to reconstruct key changes in oceanic and atmospheric circulation. These sites would have provided an unparalleled opportunity to add crucial new data and geographic coverage to existing reconstructions of Paleogene climate. In addition to the ~15 month postponement of Expedition 378 and subsequent port changes resulting in a reduction of the number of primary sites, testing and evaluation of the R/V JOIDES Resolution derrick in the weeks preceding the expedition determined that it would not support deployment of drill strings in excess of 2 km. Because of this determination, only 1 of the originally approved 7 primary sites was drilled. Expedition 378 recovered the first continuously cored, multiple-hole Paleogene sedimentary section from the southern Campbell Plateau at Site U1553. This high–southern latitude site builds on the legacy of Deep Sea Drilling Project (DSDP) Site 277, a single, partially spot cored hole, providing a unique opportunity to refine and augment existing reconstructions of the past ~66 My of climate history. This also includes the discovery of a new siliciclastic unit that had never been drilled before. As the world’s largest ocean, the Pacific Ocean is intricately linked to major changes in the global climate system. Previous drilling in the low-latitude Pacific Ocean during Ocean Drilling Program (ODP) Legs 138 and 199 and Integrated Ocean Drilling Program Expeditions 320 and 321 provided new insights into climate and carbon system dynamics, productivity changes across the zone of divergence, time-dependent calcium carbonate dissolution, bio- and magnetostratigraphy, the location of the Intertropical Convergence Zone, and evolutionary patterns for times of climatic change and upheaval. Expedition 378 in the South Pacific Ocean uniquely complements this work with a high-latitude perspective, especially because appropriate high-latitude records are unobtainable in the Northern Hemisphere of the Pacific Ocean. Site U1553 and the entire corpus of shore-based investigations will significantly contribute to the challenges of the “Climate and Ocean Change: Reading the Past, Informing the Future” theme of the IODP Science Plan (How does Earth’s climate system respond to elevated levels of atmospheric CO2? How resilient is the ocean to chemical perturbations?). Furthermore, Expedition 378 will provide material from the South Pacific Ocean in an area critical for high-latitude climate reconstructions spanning the Paleocene to late Oligocene.

Published
2020

27. Advances in Sample Preparation at the National Ocean Sciences Accelerator Mass Spectrometry Facility (NOSAMS): Investigation of Carbonate Secondary Standards

Author

Cruz, Anne J., Childress, Laurel B., Gagnon, Alan R., McNichol, Ann P., Burton, Joshua R., Elder, Kathryn L., Lardie Gaylord, Mary C., Gospodinova, Kalina D., Hlavenka, Joshua, Kurz, Mark D., Longworth, Brett E., Roberts, Mark L., Trowbridge, Nan Y., Walther, Tess, Xu, Li, Cruz, Anne J., Childress, Laurel B., Gagnon, Alan R., McNichol, Ann P., Burton, Joshua R., Elder, Kathryn L., Lardie Gaylord, Mary C., Gospodinova, Kalina D., Hlavenka, Joshua, Kurz, Mark D., Longworth, Brett E., Roberts, Mark L., Trowbridge, Nan Y., Walther, Tess, and Xu, Li

Abstract

The development of robust sample preparation techniques for ocean science research has been a hallmark of NOSAMS since its inception. Improvements to our standard methods include reducing the minimum size of the samples we can analyze, building modular graphite reactors of different sizes that we can swap in and out depending on our sample stream, and modifying our carbonate acidification methods to improve handling of the smaller samples we now receive. A relatively new instrument, the Ramped PyrOx, which allows the separation of organic matter into thermal fractions, has attracted much interest as a research and development tool. We will also discuss our progress on incorporating a Picarro isotope analyzer into our sample preparation options.

Published
2018

28. Advances in Sample Preparation at the National Ocean Sciences Accelerator Mass Spectrometry Facility (NOSAMS): Investigation of Carbonate Secondary Standards

Author

Cruz, Anne J., Childress, Laurel B., Gagnon, Alan R., McNichol, Ann P., Burton, Joshua R., Elder, Kathryn L., Lardie Gaylord, Mary C., Gospodinova, Kalina D., Hlavenka, Joshua, Kurz, Mark D., Longworth, Brett E., Roberts, Mark L., Trowbridge, Nan Y., Walther, Tess, Xu, Li, Cruz, Anne J., Childress, Laurel B., Gagnon, Alan R., McNichol, Ann P., Burton, Joshua R., Elder, Kathryn L., Lardie Gaylord, Mary C., Gospodinova, Kalina D., Hlavenka, Joshua, Kurz, Mark D., Longworth, Brett E., Roberts, Mark L., Trowbridge, Nan Y., Walther, Tess, and Xu, Li

Abstract

The development of robust sample preparation techniques for ocean science research has been a hallmark of NOSAMS since its inception. Improvements to our standard methods include reducing the minimum size of the samples we can analyze, building modular graphite reactors of different sizes that we can swap in and out depending on our sample stream, and modifying our carbonate acidification methods to improve handling of the smaller samples we now receive. A relatively new instrument, the Ramped PyrOx, which allows the separation of organic matter into thermal fractions, has attracted much interest as a research and development tool. We will also discuss our progress on incorporating a Picarro isotope analyzer into our sample preparation options.

Published
2017

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