Early Paleogene biosiliceous sedimentation in the Atlantic Ocean: Testing the inorganic origin hypothesis for Paleocene and Eocene chert and porcellanite

Witkowski, Jakub; Penman, Donald E.; Bryłka, Karolina; Wade, Bridget S.; Matting, Sabine; Harwood, David M.; Bohaty, Steven M

doi:10.1016/j.palaeo.2020.109896

Cited by 12 publications

(46 citation statements)

References 81 publications

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“…In contrast to the timing of NCW flow initiation indicated by isotopic proxy records, the onset of widespread 385 drift deposition in the North Atlantic is documented much earlier, i.e., near the termination of the EECO (~49 Ma; Hohbein et al, 2012;Boyle et al, 2017). This is also synchronous with ubiquitous deep-sea erosion coincident with the EMET (Aubry, 1995;Witkowski et al, 2020b), strongly suggesting that the onset of vigorous northern-sourced bottom current activity began at ~49-47 Ma (Vahlenkamp et al, 2018;Witkowski et al, 2020a). Following the EMET, the northward-flowing GSS and the invigorated deep WBC facilitated diapycnal mixing, which likely enhanced biological 390 pump efficiency along continental margins of the western North Atlantic.…”

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confidence: 89%

“…Direct sediment measurements of bioSiO2 concentrations (with calculated fluxes) through the Paleogene are sparse (e.g., Diester-Haass, 1995;Salamy and Zachos, 1999;Diekmann et al, 2004;Lyle et al, 2005;Iwasaki et al, 2014), and mostly focus on restricted time windows of the late Eocene through early 105 Oligocene interval. A major reason for this is that bioSiO2 is highly vulnerable to water-column and seafloor dissolution, which results in early Paleogene siliceous phytoplankton occurrences often being confined to narrow stratigraphic intervals at many sites (see Barron et al, 2015;Witkowski et al, 2020b).…”

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confidence: 99%

“…CC BY 4.0 License. framework is proposed for Site 1050 and 1051, and (2) Witkowski et al (2020b), in which Paleogene trends in chert 120 and porcellanite occurrences were compared to spatial and temporal patterns in Atlantic biosiliceous sediment occurrences. Here, we aim to determine the main controls on bioSiO2 fluxes in a key locus of biosiliceous accumulation in the Northwest Atlantic (Blake Nose) during the early-to-mid Paleogene -a period of Cenozoic climate change characterized by profound variations in global temperature.…”

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confidence: 99%

“…include only a few narrow chert and porcellanite-bearing intervals (Witkowski et al, 2020b), and sparse clinoptilolite occurrences, which suggests minimal diagenesis of sedimentary bioSiO2. As such, the good overall preservation of siliceous microplankton in Paleogene sediments at BN, combined with the exceptionally long stratigraphic span of the record recovered during Leg 171B (Witkowski et al, 2020a, and Witkowski et al, 2020b). We use the age model of Witkowski et al (2020a), who showed that the Hole 1051A succession is interrupted by two major gaps that are broadly correlative to the hiatuses in Hole 1050A (see also Röhl et al, 2003).…”

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confidence: 99%

“…Atlantic, especially along continental margins. The high diatom:radiolarian (D:R) ratios (Witkowski et al, 2020b, for further discussion see below) and common occurrence of well-preserved epiphytic diatoms such as Arachnoidiscus (see Witkowski et al, 2020a) suggest that much of BN bioSiO2 fluxes through the Paleocene may be attributed to neritic production. Varying proportions of continental runoff-derived versus upwelled nutrient input could also be invoked to explain the disparity in bioSiO2 fluxes between the more proximal Site 1051 and the more distal Site 1050 through the…”

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confidence: 99%

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North Atlantic marine biogenic silica accumulation through the early-to-mid Paleogene: implications for ocean circulation and silicate weathering feedback

Witkowski¹,

Bryłka²,

Bohaty³

et al. 2021

Preprint

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Abstract. The Paleogene history of biogenic opal accumulation in the North Atlantic provides insight into both the evolution of deep-water circulation in the Atlantic basin, and weathering responses to major climate shifts. However, existing records are compromised by low temporal resolution and/or stratigraphic discontinuities. In order to address this problem, we present a multi-site, high-resolution record of biogenic silica (bioSiO2) accumulation from Blake Nose (ODP Leg 171B, western North Atlantic) spanning the early Paleocene through late Eocene time interval (~65‒34 Ma). This record represents the longest single-locality history of marine bioSiO2 burial compiled to date and offers a unique perspective into changes in bioSiO2 fluxes through the early-to-mid Paleogene extreme greenhouse interval and subsequent period of long-term cooling. Blake Nose bioSiO2 fluxes display prominent fluctuations that we attribute to variations in sub-thermocline nutrient supply via cyclonic eddies associated with the Gulf Stream. Whereas few constraints are available on the bioSiO2 flux pulses peaking in the early Paleocene and early Eocene, a middle Eocene interval of elevated bioSiO2 flux between ~46 and 42 Ma is proposed to reflect nutrient enrichment due to invigorated overturning circulation following an early onset of Northern Component Water export from the Norwegian-Greenland Sea at ~49 Ma. Comparison of our North Atlantic record against published Pacific bioSiO2 flux records indicates a diminished nutrient supply to the Atlantic between ~42 and 38 Ma, interpreted as a response to weakening of the overturning circulation. Subsequently, a deep-water circulation regime favoring limited bioSiO2 burial in Atlantic and enhanced bioSiO2 burial in the Pacific was established after ~38 Ma, likely in association with a further invigoration of deep-water export from the North Atlantic. We also observe that Blake Nose bioSiO2 fluxes through the middle Eocene cooling interval (~48 to 34 Ma) are consistently higher than background fluxes throughout the late Paleocene‒early Eocene interval of intense greenhouse warmth. This observation is consistent with a temporally variable rather than constant silicate weathering feedback strength model for the Paleogene, which would instead predict that marine bioSiO2 burial should peak during periods of extreme warming.

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confidence: 89%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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North Atlantic marine biogenic silica accumulation through the early-to-mid Paleogene: implications for ocean circulation and silicate weathering feedback

Witkowski¹,

Bryłka²,

Bohaty³

et al. 2021

Preprint

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Natural Variability Versus Anthropogenic Impacts on Deep-Sea Ecosystems of Importance for Deep-Sea Mining

Radziejewska

Mianowicz

Abramowski

2022

Perspectives on Deep-Sea Mining

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Evolution of deep-sea sediments across the Paleocene-Eocene and Eocene-Oligocene boundaries

Wade

O’Neill

Phujareanchaiwon

et al. 2020

Earth-Science Reviews

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The composition and distribution of deep-sea sediments is the result of a multitude of climatic, biotic and oceanic conditions relating to biogeochemical cycles and environmental change. Here we utilize the extensive sediment archives of the International Ocean Discovery Program (IODP) and its predecessors to construct maps of deep-sea sediment type across two critical but contrasting boundaries in the Paleogene, one characterised by an interval of extreme warmth (Paleocene/Eocene) and the other by global cooling (Eocene/Oligocene). Ocean 2 sediment distribution shows significant divergence both between the latest Paleocene and Paleocene Eocene Thermal Maximum (PETM), across the Eocene-Oligocene Transition (EOT), and in comparison to modern sediment distributions. Carbonate sedimentation in the latest Paleocene extends to high southern latitudes. Disappearance of carbonate sediments at the PETM is well documented and can be attributed to dissolution caused by significant ocean acidification as a result of carbon-cycle perturbation. Biosiliceous sediments are rare and it is posited that the reduced biogenic silica deposition at the equator is commensurate with an overall lack of equatorial upwelling in the early Paleogene ocean. In the Southern Ocean, we attribute the low in biosiliceous burial, to the warm deep water temperatures which would have impacted biogenic silica preservation. In the late Eocene, our sediment depositional maps record a tongue of radiolarian ooze in the eastern equatorial Pacific. Enhanced biosiliceous deposits in the late Eocene equatorial Pacific and Southern Ocean are due to increased productivity and the spin-up of the oceans. Our compilation documents the enhanced global carbonate sedimentation in the early Oligocene, confirming that the drop in the carbonate compensation depth was global.

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Early Paleogene biosiliceous sedimentation in the Atlantic Ocean: Testing the inorganic origin hypothesis for Paleocene and Eocene chert and porcellanite

Cited by 12 publications

References 81 publications

North Atlantic marine biogenic silica accumulation through the early-to-mid Paleogene: implications for ocean circulation and silicate weathering feedback

North Atlantic marine biogenic silica accumulation through the early-to-mid Paleogene: implications for ocean circulation and silicate weathering feedback

Natural Variability Versus Anthropogenic Impacts on Deep-Sea Ecosystems of Importance for Deep-Sea Mining

Evolution of deep-sea sediments across the Paleocene-Eocene and Eocene-Oligocene boundaries

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