Site U1406

Norris, Richard D.; Wilson, Paul A.; Blum, Peter; Fehr, A.; Agnini, Claudia; Bornemann, André; Boulila, Slah; Bown, Paul R.; Cournède, C.; Friedrich, Oliver; Ghosh, Amit K.; Hollis, Christopher J.; Hull, Pincelli M.; Jo, Kyoung Nam; Junium, Christopher K.; Kaneko, Masanori; Liebrand, Diederik; Lippert, Peter C.; Liu, Z.; Matsui, Hiroki; Moriya, Kazuyoshi; Nishi, Hiroshi; Opdyke, Bradley N.; Penman, Donald E.; Romans, Brian W.; Scher, Howie D.; Sexton, Philip F; Takagi, Hirofumi; Turner, S. Kirtland; Whiteside, Jessica H.; Yamaguchi, Tatsuhiko; Yamamoto, Yuhji

doi:10.2204/iodp.proc.342.107.2014

Cited by 18 publications

(55 citation statements)

References 14 publications

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“…XRF elemental counts were generated using an Avaatech XRF Core Scanner at the Gulf Coast Repository (Texas, USA), equipped with an Oxford Instruments 100W Neptune Rh X-ray tube and a Canberra X-PIPS detector. The X-ray tube was run at 10 kV and 1000 µA, the measurement area was set with a cross-core slit of 10 mm and a downcore slit of 12 mm, and measurements were taken at 2 cm intervals with a live counting time of 20 s. For some intervals where XRF data alone do not yield satisfactory correlations, we correlated intervals using physical properties data (i.e., magnetic susceptibility, GRA, NGR, and color reflectance; see the "Site U1406" chapter [Norris et al, 2014c] The composite depth scale, core composite depth below seafloor (CCSF; equivalent to meters composite depth in ODP nomenclature), is defined by adding offsets to the CSF-A depths of cores to align correlative features in cores from multiple holes, simultaneously eliminating overlaps and filling in core gaps. We named the composite depth scale CCSF-A to emphasize that the CCSF depth scale is the composite version of the CSF-A scale.…”

Section: Methodsmentioning

confidence: 99%

“…The core depth shifts that define the CCSF-A scale are based on one correlative feature between any two cores; this depth scale does not involve stretching and squeezing because it is an affine transformation. Here, we revise the shipboard offsets given to cores in the "Site U1406" chapter (Norris et al, 2014c) and present a revised CCSF-A depth scale for Site U1406. In cases where no correlation tie points could be established, we shifted the tops of cores 1 m below the bottom of the previous core, instead of the +0.01 m used for the shipboard splice (see the "Site U1406" chapter [Norris et al, 2014c]).…”

Section: Methodsmentioning

confidence: 99%

“…The modest variability of the physical properties data (i.e., magnetic susceptibility, gamma ray attenuation [GRA], and natural gamma radiation [NGR]) from the clay-rich drift sediments at Site U1406 challenged the construction of a reliable shipboard splice (see the "Site U1406" chapter [Norris et al, 2014c]). Postexpedition high-resolution X-ray fluorescence (XRF) core scanning, however, has made it possible to construct a decimeter-scale composite depth scale and near-continuous spliced record.…”

Section: Introductionmentioning

confidence: 99%

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Data report: revised composite depth scale and splice for IODP Site U1406

Peer¹,

Liebrand²,

Xuan³

et al. 2017

Proceedings of the IODP

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Integrated Ocean Drilling Program (IODP) Expedition 342 recovered exceptional Paleogene to early Neogene sedimentary archives from clay-rich sediments in the northwest Atlantic Ocean. These archives present an opportunity to study Cenozoic climate in a highly sensitive region at often unprecedented resolution. Such studies require continuous records in the depth and time domains. Using records from multiple adjacent drilled holes, intervals within consecutive cores are typically spliced into a single composite record on board the R/V JOIDES Resolution using highresolution physical properties data sets acquired before the cores are split. The highly dynamic nature of the sediment drifts drilled during Expedition 342 and the modest amplitude of variance in the physical property records made it possible to construct only highly tentative initial working splices, which require extensive postexpedition follow-up work. Postexpedition, high-resolution X-ray fluorescence (XRF) core scanning data enabled the construction of a preliminary composite depth scale and splice. Here, we present the revised composite depth scale and splice for IODP Site U1406, predominantly constructed using detailed hole-tohole correlations of newly generated high-resolution XRF data and revisions of the initial XRF data set. The revised composite depth scale and splice serve as a reference framework for future research on Site U1406 sediments. IntroductionIntegrated Ocean Drilling Program (IODP) Expedition 342, "Paleogene Newfoundland Sediment Drifts," was completed during June and July 2012 and recovered a total of ~5.4 km of predominantly Paleogene clay-rich sediments (see the "Expedition 342 summary" and "Methods" chapters [Norris et al., 2014a[Norris et al., , 2014b). The nine sites drilled on the J-Anomaly and Newfoundland Ridges span a depth transect from ~4.9 km (Site U1403) tõ 3.0 km water depth (Site U1408). The sites at the J-Anomaly Ridge (Sites U1403-U1406) recovered expanded records (up to 25 cm/ky at Site U1405) of late Paleogene to early Neogene age.Site U1406 (40˚21′N, 51˚39′W; Fig. F1)

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Data report: revised composite depth scale and splice for IODP Site U1406

Peer¹,

Liebrand²,

Xuan³

et al. 2017

Proceedings of the IODP

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“…XRF scans of Fe at 10 kV were used to generate a revised spliced depth scale (meters composite depth [mcd]) for Sites U1408 and U1409 that we use here (see 342_REV_SPLICE in SPLICE in "Supplementary material"). For Sites U1406 and U1411, we use the shipboard splices (see 342_SPLICE in SPLICE in "Supplementary material") and the corresponding site reports (see the "Site U1406" and "Site U1411" chapters [Norris et al, 2014b. The splice from Site U1408 is still under revision and is being considered with a direct comparison with Site U1410, particularly for Magnetochrons C18, C19, and C20r.…”

Section: Methodsmentioning

confidence: 99%

“…IODP | Volume 342composite depth below seafloor, or CCSF, in other Expedition 342 publications), and shipboard bioand magnetostrat-derived age models for every sample. Sample IDs for all shipboard stratigraphic tie points were obtained from the relevant site reports (see the "Site U1406," "Site U1408," "Site U1409," and "Site U1411" chapters [Norris et al, 2014b[Norris et al, , 2014c[Norris et al, , 2014d). Several inconsistencies in the meters below seafloor assignments in the shipboard reports were identified by P. Blum on review, so we updated all assignments for the sample IDs of the stratigraphic tie points using the Laboratory Information Management System (LIMS) Report system (http://web.iodp.tamu.edu/LORE/).…”

Section: Data Report: Coarse Fraction Recordmentioning

confidence: 99%

Data report: relative abundance of benthic foraminiferal morphotypes across the Eocene/Oligocene and Oligocene/Miocene boundaries (IODP Expedition 342 Site U1406|North Atlantic)

Hull¹,

Bohaty²,

Cameron³

et al. 2017

Proceedings of the IODP

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Integrated Ocean Drilling Program Expedition 342 recovered cores from multiple sites with expanded sections of Eocene sediments, often with exceptional carbonate preservation. These cores presented the opportunity to build an Eocene-spanning, orbital-resolution megasplice for refining the Eocene timescale and detailing paleoceanographic change in a high-latitude North Atlantic location. Here we present a sediment coarse fraction record (i.e., a record of the relative portion of >63 µm sized sedimentary particles), considered alongside shipboard estimates of sedimentation rates, from 8,674 of the 10,829 samples of the Eocene megasplice. Weight percent coarse fraction (wt% CF) data were collected in 10 different laboratories, but we find that long-term trends in wt% CF are robust to interlaboratory differences in sample processing. In particular, this record details a progressive decline in wt% CF from around 5%-8% around 50 Ma to lows of less than 1% around 36 Ma. The decline in weight percent carbonate from ~50-36 Ma is not monotonic; rather, it is interrupted by at least four local highs at around 46.5, 44, 41.7, and 39 Ma. Interestingly, the abrupt onset of drift sedimentation in the early middle Eocene at Site U1409 (~47 Ma) does not coincide with a step decline in wt% CF. Because the early Eocene section of Site U1409 has lower sedimentation rates (mean = 0.99 cm/ky) compared to the middle Eocene section of Site U1408 (mean = 3.08 cm/ky), the generally lower wt% CaC0 3 in the middle Eocene section of Site U1408 was hypothesized to be driven by clay dilution in shipboard discussions. However, within the sites with variable sedimentation rates (i.e., Sites U1411, U1406, U1408, and U1409), wt% CF exhibited weak covariance with sedimentation rates (highest r 2 = 0.112; significant p-values for Sites U1411 and U1408 on pairwise correlation tests). Precise age models are thus needed to further resolve the relationship between the mass accumulation of clay, nannofossils, and foraminifer-dominated coarse fraction in these sections. Finally, within well-resolved intervals like the middle Eocene section of Site U1408, orbital scale variability is present in the wt% CF record, supporting shipboard observations of pronounced orbital variation in drift lithology (e.g., core color and weight percent carbonate).

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Extracting a Detailed Magnetostratigraphy From Weakly Magnetized, Oligocene to Early Miocene Sediment Drifts Recovered at IODP Site U1406 (Newfoundland Margin, Northwest Atlantic Ocean)

Peer

Xuan

Lippert

et al. 2017

Geochem Geophys Geosyst

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Fine‐grained magnetic particles in deep‐sea sediments often statistically align with the ambient magnetic field during (and shortly after) deposition and can therefore record geomagnetic reversals. Correlation of these reversals to a geomagnetic polarity time scale is an important geochronological tool that facilitates precise stratigraphic correlation and dating of geological records globally. Sediments often carry a remanence strong enough for confident identification of polarity reversals, but in some cases a low signal‐to‐noise ratio prevents the construction of a reliable and robust magnetostratigraphy. Here we implement a data‐filtering protocol, which can be integrated with the UPmag software package, to automatically reduce the maximum angular deviation and statistically mask noisy data and outliers deemed unsuitable for magnetostratigraphic interpretation. This protocol thus extracts a clearer signal from weakly magnetized sediments recovered at Integrated Ocean Drilling Program (IODP) Expedition 342 Site U1406 (Newfoundland margin, northwest Atlantic Ocean). The resulting magnetostratigraphy, in combination with shipboard and shore‐based biostratigraphy, provides an age model for the study interval from IODP Site U1406 between Chrons C6Ar and C9n (∼21–27 Ma). We identify rarely observed geomagnetic directional changes within Chrons C6Br, C7r, and C7Ar, and perhaps within Subchron C8n.1n. Our magnetostratigraphy dates three intervals of unusual stratigraphic behavior within the sediment drifts at IODP Site U1406 on the Newfoundland margin. These lithostratigraphic changes are broadly concurrent with the coldest climatic phases of the middle Oligocene to early Miocene and we hypothesize that they reflect changes in bottom water circulation.

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Site U1406

Cited by 18 publications

References 14 publications

Data report: revised composite depth scale and splice for IODP Site U1406

Data report: revised composite depth scale and splice for IODP Site U1406

Data report: relative abundance of benthic foraminiferal morphotypes across the Eocene/Oligocene and Oligocene/Miocene boundaries (IODP Expedition 342 Site U1406|North Atlantic)

Extracting a Detailed Magnetostratigraphy From Weakly Magnetized, Oligocene to Early Miocene Sediment Drifts Recovered at IODP Site U1406 (Newfoundland Margin, Northwest Atlantic Ocean)

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