Evaluating the tephra input into Pacific Ocean sediments: distribution in space and time

Straub, Susanne M.; Schmincke, Hans‐Ulrich

doi:10.1007/s005310050222

Cited by 57 publications

(39 citation statements)

References 57 publications

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“…Indeed, this issue is likely common to all ocean sediments lying in areas influenced by deposition of volcanic material. Such areas may not simply be restricted to locations immediately around active island volcanoes, as exemplified by estimates Page | 23 that ~25% of Pacific Ocean sediment comprises volcanogenic material (Straub and Schmincke, 1998). …”

Section: Methods Testingmentioning

confidence: 99%

Construction of volcanic records from marine sediment cores: A review and case study (Montserrat, West Indies)

Cassidy

Watt

Palmer

et al. 2014

Earth-Science Reviews

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Detailed knowledge of the past history of an active volcano is crucial for the prediction of the timing, frequency and style of future eruptions, and for the identification of potentially at-risk areas. Subaerial volcanic stratigraphies are often incomplete, due to a lack of exposure, or burial and erosion from subsequent eruptions. However, many volcanic eruptions produce widelydispersed explosive products that are frequently deposited as tephra layers in the sea. Cores of marine sediment therefore have the potential to provide more complete volcanic stratigraphies, at least for explosive eruptions. Nevertheless, problems such as bioturbation and dispersal by currents affect the preservation and subsequent detection of marine tephra deposits.Consequently, cryptotephras, in which tephra grains are not sufficiently concentrated to form layers that are visible to the naked eye, may be the only record of many explosive eruptions.Additionally, thin, reworked deposits of volcanic clasts transported by floods and landslides, or during pyroclastic density currents may be incorrectly interpreted as tephra fallout layers, leading to the construction of inaccurate records of volcanism. This work uses samples from the volcanic island of Montserrat as a case study to test different techniques for generating volcanic eruption records from marine sediment cores, with a particular relevance to cores sampled in relatively proximal settings (i.e. tens of kilometres from the volcanic source) where volcaniclastic material may form a pervasive component of the sedimentary sequence. Visible volcaniclastic deposits identified by sedimentological logging were used to test the effectiveness of potential alternative volcaniclastic-deposit detection techniques, including point counting of grain types (component analysis), glass or mineral chemistry, colour spectrophotometry, grain size measurements, XRF core scanning, magnetic susceptibility and X-radiography. This study demonstrates that a set of time-efficient, non-destructive and high-spatial-resolution analyses (e.g. XRF core-scanning and magnetic susceptibility) can be used effectively to detect potential cryptotephra horizons in marine sediment cores. Once these horizons have been sampled, microscope image analysis of volcaniclastic grains can be used successfully to discriminate between tephra fallout deposits and other volcaniclastic deposits, by using specific criteria Page | 3 related to clast morphology and sorting. Standard practice should be employed when analysing marine sediment cores to accurately identify both visible tephra and cryptotephra deposits, and to distinguish fallout deposits from other volcaniclastic deposits.

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Section: Methods Testingmentioning

confidence: 99%

Construction of volcanic records from marine sediment cores: A review and case study (Montserrat, West Indies)

Cassidy

Watt

Palmer

et al. 2014

Earth-Science Reviews

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“…Such input would be enough to cause significant MPP response in an iron-limited (HNLC) oceanic area, as >2 nM Fe-increase were shown in mesoscale ironenrichment experiments to be sufficient to stimulate a massive phytoplankton bloom (Wells, 2003). Further, deep oceanic sediments, including those in iron-limited HNLC areas, contain ash layers with thickness on the mm-, dm-and even up to the meter-scale (Straub and Schmincke, 1998). Thus, heavy volcanic ash fall may swamp the surface of the ocean with iron, at least within the ash fall-out area.…”

Section: Giving Birth To a New Interdisciplinary Research Focus -Overmentioning

confidence: 99%

The role of airborne volcanic ash for the surface ocean biogeochemical iron-cycle: a review

et al. 2010

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Abstract. Iron is a key micronutrient for phytoplankton growth in the surface ocean. Yet the significance of volcanism for the marine biogeochemical iron-cycle is poorly constrained. Recent studies, however, suggest that offshore deposition of airborne ash from volcanic eruptions is a way to inject significant amounts of bio-available iron into the surface ocean. Volcanic ash may be transported up to several tens of kilometers high into the atmosphere during largescale eruptions and fine ash may stay aloft for days to weeks, thereby reaching even the remotest and most ironstarved oceanic regions. Scientific ocean drilling demonstrates that volcanic ash layers and dispersed ash particles are frequently found in marine sediments and that therefore volcanic ash deposition and iron-injection into the oceans took place throughout much of the Earth's history. Natural evidence and the data now available from geochemical and biological experiments and satellite techniques suggest that volcanic ash is a so far underestimated source for iron in the surface ocean, possibly of similar importance as aeolian dust. Here we summarise the development of and the knowledge in this fairly young research field. The paper Correspondence to: S. Duggen (svend duggen@skoleforeningen.de) covers a wide range of chemical and biological issues and we make recommendations for future directions in these areas. The review paper may thus be helpful to improve our understanding of the role of volcanic ash for the marine biogeochemical iron-cycle, marine primary productivity and the ocean-atmosphere exchange of CO 2 and other gases relevant for climate in the Earth's history.

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“…Jones and Gislason, 2008;Duggen et al, 2007;Frogner et al, 2001). Drill core data from scientific ocean drilling show that volcanic ash layers and dispersed ash particles are frequently found in marine sediments and that volcanic ash deposition and therefore iron-injection into the oceans took place throughout much of the Earths history (Straub and Schmincke, 1998). It may thus well be possible that the contribution of volcanic ash to the marine biogeochemical ironcycle is generally underestimated.…”

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confidence: 99%

Iron biogeochemistry across marine systems – progress from the past decade

et al. 2010

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Abstract. Based on an international workshop (Gothenburg, 14-16 May 2008), this review article aims to combine interdisciplinary knowledge from coastal and open ocean research on iron biogeochemistry. The major scientific findings of the past decade are structured into sections on natural and artificial iron fertilization, iron inputs into coastal and estuarine systems, colloidal iron and organic matter, and biological processes. Potential effects of global climate change, particularly ocean acidification, on iron biogeochemistry are discussed. The findings are synthesized into recommendations for future research areas.Correspondence to: E. Breitbarth (ebreitbarth@chemistry.otago.ac.nz)

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Evaluating the tephra input into Pacific Ocean sediments: distribution in space and time

Cited by 57 publications

References 57 publications

Construction of volcanic records from marine sediment cores: A review and case study (Montserrat, West Indies)

Construction of volcanic records from marine sediment cores: A review and case study (Montserrat, West Indies)

The role of airborne volcanic ash for the surface ocean biogeochemical iron-cycle: a review

Iron biogeochemistry across marine systems – progress from the past decade

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