Your search keyword '"Dove Basin"' showing total 8 results

1. Site U1537.

Author

Weber, M. E., Raymo, M. E., Peck, V. L., Williams, T., Armbrecht, L. H., Bailey, I., Brachfeld, S. A., Cardillo, F. G., Du, Z., Fauth, G., García, M., Glüder, A., Guitard, M. E., Gutjahr, M., Hemming, S. R., Hernández-Almeida, I., Hoem, F. S., Hwang, J.-H., Iizuka, M., and Kato, Y.

Subjects

PALEOCEANOGRAPHY, CLIMATE change, OCEAN dynamics

Published

2021

2. Expedition 382 methods.

Author

Weber, M. E., Raymo, M. E., Peck, V. L., Williams, T., Armbrecht, L. H., Bailey, I., Brachfeld, S. A., Cardillo, F. G., Du, Z., Fauth, G., García, M., Glüder, A., Guitard, M. E., Gutjahr, M., Hemming, S. R., Hernández-Almeida, I., Hoem, F. S., Hwang, J.-H., Iizuka, M., and Kato, Y.

Subjects

OCEAN dynamics, GLOBAL Positioning System, DRILL pipe, DATA analysis

Published

2021

3. Expedition 382 summary.

Author

Weber, M. E., Raymo, M. E., Peck, V. L., Williams, T., Armbrecht, L. H., Bailey, I., Brachfeld, S. A., Cardillo, F. G., Du, Z., Fauth, G., García, M., Glüder, A., Guitard, M. E., Gutjahr, M., Hemming, S. R., Hernández-Almeida, I., Hoem, F. S., Hwang, J.-H., Iizuka, M., and Kato, Y.

Subjects

ATMOSPHERIC carbon dioxide, CLIMATE change, ATMOSPHERIC circulation

Abstract

International Ocean Discovery Program Expedition 382, Iceberg Alley and Subantarctic Ice and Ocean Dynamics, investigated the long-term climate history of Antarctica, seeking to understand how polar ice sheets responded to changes in insolation and atmospheric CO2 in the past and how ice sheet evolution influenced global sea level and vice versa. Five sites (U1534-U1538) were drilled east of the Drake Passage: two sites at 53.2°S at the northern edge of the Scotia Sea and three sites at 57.4°-59.4°S in the southern Scotia Sea. We recovered continuously deposited late Neogene sediments to reconstruct the past history and variability in Antarctic Ice Sheet (AIS) mass loss and associated changes in oceanic and atmospheric circulation. [ABSTRACT FROM AUTHOR]

Published

2021

4. New Magnetostratigraphic Insights From Iceberg Alley on the Rhythms of Antarctic Climate During the Plio‐Pleistocene.

Author

Reilly, Brendan T., Tauxe, Lisa, Brachfeld, Stefanie, Raymo, Maureen, Bailey, Ian, Hemming, Sidney, Weber, Michael E., Williams, Trevor, Garcia, Marga, Guitard, Michelle, Martos, Yasmina M., Pérez, Lara F., Zheng, Xufeng, Armbrecht, Linda, Cardillo, Fabricio G., Du, Zhiheng, Fauth, Gerson, Glueder, Anna, Gutjahr, Marcus, and Hernández‐Almeida, Iván

Subjects

ANTARCTIC climate, AMPLITUDE modulation, ICEBERGS, ICE sheets, ANTARCTIC ice, SUBGLACIAL lakes

Abstract

International Ocean Discovery Program (IODP) Expedition 382 in the Scotia Sea's Iceberg Alley recovered among the most continuous and highest resolution stratigraphic records in the Southern Ocean near Antarctica spanning the last 3.3 Myr. Sites drilled in Dove Basin (U1536/U1537) have well‐resolved magnetostratigraphy and a strong imprint of orbital forcing in their lithostratigraphy. All magnetic reversals of the last 3.3 Myr are identified, providing a robust age model independent of orbital tuning. During the Pleistocene, alternation of terrigenous versus diatomaceous facies shows power in the eccentricity and obliquity frequencies comparable to the amplitude modulation of benthic δ18O records. This suggests that variations in Dove Basin lithostratigraphy during the Pleistocene reflect a similar history as globally integrated ice volume at these frequencies. However, power in the precession frequencies over the entire ∼3.3 Myr record does not match the amplitude modulation of benthic δ18O records, suggesting Dove Basin contains a unique record at these frequencies. Comparing the position of magnetic reversals relative to local facies changes in Dove Basin and the same magnetic reversals relative to benthic δ18O at North Atlantic IODP Site U1308, we demonstrate Dove Basin facies change at different times than benthic δ18O during intervals between ∼3 and 1 Ma. These differences are consistent with precession phase shifts and suggest climate signals with a Southern Hemisphere summer insolation phase were recorded around Antarctica. If Dove Basin lithology reflects local Antarctic ice volume changes, these signals could represent ice sheet precession‐paced variations not captured in benthic δ18O during the 41‐kyr world. Key Points: Extended composite and correlated equivalent depth scales are presented for Antarctic proximal International Ocean Discovery Program Sites U1536 and U1537U1536 and U1537 have excellent magnetostratigraphy and clear imprint of orbital variations in their lithologyChanges in terrigenous versus diatomaceous Dove Basin facies are out of phase with benthic δ18O during intervals between 3.3 and 1 Ma [ABSTRACT FROM AUTHOR]

Published

2021

5. Recent morpho-sedimentary processes in Dove Basin, southern Scotia Sea, Antarctica: A basin-scale case of interaction between bottom currents and mass movements

Author

Ministerio de Ciencia e Innovación (España), European Commission, Royal Holloway, University of London, Lobo, F. J., López-Quirós, Adrián, Hernández-Molina, Francisco J., Pérez, Lara F., García, M., Evangelinos, Dimitris, Bohoyo, Fernando, Rodríguez-Fernández, José, Salabarnada, Ariadna, Maldonado, Andrés, Ministerio de Ciencia e Innovación (España), European Commission, Royal Holloway, University of London, Lobo, F. J., López-Quirós, Adrián, Hernández-Molina, Francisco J., Pérez, Lara F., García, M., Evangelinos, Dimitris, Bohoyo, Fernando, Rodríguez-Fernández, José, Salabarnada, Ariadna, and Maldonado, Andrés

Abstract

Multibeam bathymetric imagery and acoustic sub-bottom profiles are used to reveal distribution patterns of sub-surface sedimentation in Dove Basin (Scotia Sea). The goals of the study are to determine the imprint of the inflow of deep Antarctic water masses from the Weddell Sea into the Scotia Sea, to establish the factors driving the styles of contourite deposition and to discern the relative contribution of alongslope versus downslope processes to the construction of the uppermost late Quaternary sedimentary record in the basin. The most significant morpho-sedimentary features in Dove Basin are linked to contouritic processes and to mass movements. Plastered drifts on the flanks of the basin constitute the most common contouritic deposits. Basement-controlled drifts on top of structural elevations are common along the central ridge, the central basin plain and scattered along the basin flanks. Sheeted drifts occur on top of adjacent banks or are restricted to the deep basin. In contrast, mounded drifts are poorly represented in Dove basin. A laterally extensive contouritic channel runs along the central ridge. Contouritic channels are also identified in the upper parts of the lateral banks and slopes. Numerous slide scars along the upper parts of the slopes evolve downslope into semitransparent lens-shaped bodies, with occasional development of across-slope channels. Semitransparent lenses occur intercalated within stratified deposits in the slopes of the basin, in the central ridge and in the deepest basin plain. The spatial arrangement of contouritic morphologies points to the influence of the water column structure and the basin physiography. In the eastern sub-basin, two different fractions (lower and upper) of Weddell Sea Deep Water (WSDW) leave an imprint on contourite deposits owing to the sloping interface between the two fractions. Contouritic influence is more subdued in the western sub-basin, and limited to the imprint of the lower WSDW. The upper parts

Published

2021

6. Recent morpho-sedimentary processes in Dove Basin, southern Scotia Sea, Antarctica: A basin-scale case of interaction between bottom currents and mass movements

Author

Francisco Javier Hernandéz-Molina, Andrés Maldonado, Fernando Bohoyo, Francisco J. Lobo, José Luis Rodríguez-Fernández, Ariadna Salabarnada, Adrián López-Quirós, Dimitris Evangelinos, Lara F. Pérez, Marga García, Ministerio de Ciencia e Innovación (España), European Commission, and Royal Holloway, University of London

Subjects

Water mass, geology, 010504 meteorology & atmospheric sciences, Antarctic Circumpolar Current, earth, Structural basin, 010502 geochemistry & geophysics, Oceanography, Centro Oceanográfico de Cádiz, 01 natural sciences, Scotia Sea, Paleontology, Continental margin, Geochemistry and Petrology, Circumpolar deep water, earth sciences, 14. Life underwater, Medio Marino, 0105 earth and related environmental sciences, geography, Contourites, geography.geographical_feature_category, Gravity flows, Dove Basin, Contourite, Basement (geology), 13. Climate action, Ridge, Sedimentary rock, Sub-bottom stratigraphy, bottom currents, marine geology, Weddell Sea Deep Water, Geology

Abstract

Funding for this research was provided by the Spanish Ministry of Science and Innovation (grants CTM2014-60451-C2-1/2-P and CTM2017-89711-C2-1/2-P) co-funded by the European Union through FEDER funds. The research was conducted in collaboration with `The Drifters Research Group' of the Royal Holloway University of London (UK), and is also related to the projects CTM 2012-39599-C03, CGL2016-80445-R, CTM2016-75129-C3-1-R and CGL2015-74216-JIN. We thank the commander, officers and crew of the BIO HESPERIDES for their support in obtaining the data, sometimes under severe sea conditions. Jean Sanders reviewed the English style of the manuscript. Rob Larter (BAS, UK) and an anonymous reviewer provided numeroususeful remarks that improved an initial version of the manuscript. Seismic interpretations were made using the IHS Kingdom T software, thanks to the participation of the Instituto Andaluz de Ciencias de la Tierra in the IHS University Grant program., Multibeam bathymetric imagery and acoustic sub-bottom profiles are used to reveal distribution patterns of subsurface sedimentation in Dove Basin (Scotia Sea). The goals of the study are to determine the imprint of the inflow of deep Antarctic water masses from the Weddell Sea into the Scotia Sea, to establish the factors driving the styles of contourite deposition and to discern the relative contribution of alongslope versus downslope processes to the construction of the uppermost late Quaternary sedimentary record in the basin. The most significant morpho-sedimentary features in Dove Basin are linked to contouritic processes and to mass movements. Plastered drifts on the flanks of the basin constitute the most common contouritic deposits. Basement-controlled drifts on top of structural elevations are common along the central ridge, the central basin plain and scattered along the basin flanks. Sheeted drifts occur on top of adjacent banks or are restricted to the deep basin. In contrast, mounded drifts are poorly represented in Dove basin. A laterally extensive contouritic channel runs along the central ridge. Contouritic channels are also identified in the upper parts of the lateral banks and slopes. Numerous slide scars along the upper parts of the slopes evolve downslope into semitransparent lens-shaped bodies, with occasional development of across-slope channels. Semitransparent lenses occur intercalated within stratified deposits in the slopes of the basin, in the central ridge and in the deepest basin plain. The spatial arrangement of contouritic morphologies points to the influence of the water column structure and the basin physiography. In the eastern sub-basin, two different fractions (lower and upper) of Weddell Sea Deep Water (WSDW) leave an imprint on contourite deposits owing to the sloping interface between the two fractions. Contouritic influence is more subdued in the western sub-basin, and limited to the imprint of the lower WSDW. The upper parts of the surrounding banks are under the influence of deep-reaching Circumpolar waters (i.e., Lower Circumpolar Deep Water), which develops both depositional and erosional morphologies. The crosssection V-shaped morphology of the basin and the common occurrence of structural highs drive the predominance of plastered and basement-controlled drifts in the sediment record. The frequent alternation between contourites and downslope gravity-flow deposits is likely due to different processes associated with oversteepening in the basin, such as basement-controlled steep slopes, deformed drifts atop basement elevations, and the development of thick contouritic piles. Dove Basin is an example of a basin without mounded, plastered or mixed hybrid drifts in the transition between the lower slope and the deep basin, because the upper boundary of the deepest water mass —the Weddell Sea Deep Water— flows shallower along the middle slope. This fact underlines the relevance of the position and depth of water masses in shaping the morphology of the feet of slopes along continental margins., Spanish Ministry of Science and Innovation - European Union through FEDER funds CTM2014-60451-C2-1/2-P CTM2017-89711-C2-1/2-P CTM 2012-39599-C03 CGL2016-80445-R CTM2016-75129-C3-1-R CGL2015-74216-JIN

Published

2021

7. New Magnetostratigraphic Insights From Iceberg Alley on the Rhythms of Antarctic Climate During the Plio‐Pleistocene

Author

Lara F. Pérez, Iván Hernández-Almeida, Marcus Gutjahr, Jonathan P. Warnock, Stefanie Ann Brachfeld, Maureen E. Raymo, Sidney R. Hemming, Ji Hwan Hwang, Anna Glueder, Lisa Tauxe, Michael E Weber, Michelle Guitard, Thomas A Ronge, Brendan T Reilly, Suzanne O'Connell, Ian Bailey, Yuji Kato, Xufeng Zheng, Marga García, Frida S. Hoem, Shubham Tripathi, Yasmina M. Martos, Zhiheng Du, Osamu Seki, Victoria L Peck, Bridget Kenlee, Fabricio G. Cardillo, Trevor Williams, Linda Armbrecht, Gerson Fauth, and Mutsumi Iizuka

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Pleistocene, Orbital forcing, International Ocean Discovery Program (IODP), 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Scotia Sea, Paleontology, Antártida, 14. Life underwater, magnetostratigraphy, Magnetostratigraphy, Magneto-estratigrafía, 0105 earth and related environmental sciences, amplitude, magnetic reversals, Iceberg Alley, geography, geography.geographical_feature_category, Lithostratigraphy, Dove Basin, Plio-Pleistocene, International Ocean Discovery Program, Iceberg, facies, 13. Climate action, Antarctica, Plio-Pleistoceno, pleistocene, Ice sheet, Geology

Abstract

International Ocean Discovery Program (IODP) Expedition 382 in the Scotia Sea’s Iceberg Alley recovered among the most continuous and highest resolution stratigraphic records in the Southern Ocean near Antarctica spanning the last 3.3 Myr. Sites drilled in Dove Basin (U1536/U1537) have well-resolved magnetostratigraphy and a strong imprint of orbital forcing in their lithostratigraphy. All magnetic reversals of the last 3.3 Myr are identified, providing a robust age model independent of orbital tuning. During the Pleistocene, alternation of terrigenous versus diatomaceous facies shows power in the eccentricity and obliquity frequencies comparable to the amplitude modulation of benthic δ18O records. This suggests that variations in Dove Basin lithostratigraphy during the Pleistocene reflect a similar history as globally integrated ice volume at these frequencies. However, power in the precession frequencies over the entire ∼3.3 Myr record does not match the amplitude modulation of benthic δ18O records, suggesting Dove Basin contains a unique record at these frequencies. Comparing the position of magnetic reversals relative to local facies changes in Dove Basin and the same magnetic reversals relative to benthic δ18O at North Atlantic IODP Site U1308, we demonstrate Dove Basin facies change at different times than benthic δ18O during intervals between ∼3 and 1 Ma. These differences are consistent with precession phase shifts and suggest climate signals with a Southern Hemisphere summer insolation phase were recorded around Antarctica. If Dove Basin lithology reflects local Antarctic ice volume changes, these signals could represent ice sheet precession-paced variations not captured in benthic δ18O during the 41-kyr world.

Published

2021

8. Recent morpho-sedimentary processes in Dove Basin, southern Scotia Sea, Antarctica: A basin-scale case of interaction between bottom currents and mass movements.

Author

Lobo, F.J., López-Quirós, A., Hernández-Molina, F.J., Pérez, L.F., García, M., Evangelinos, D., Bohoyo, F., Rodríguez-Fernández, J., Salabarnada, A., and Maldonado, A.

Subjects

*WATER masses, *CONTINENTAL slopes, *SETTLING basins, *SEAWATER, *TERRITORIAL waters, *MASS-wasting (Geology), *SEDIMENTARY basins, *GLACIAL drift

Abstract

Multibeam bathymetric imagery and acoustic sub-bottom profiles are used to reveal distribution patterns of sub-surface sedimentation in Dove Basin (Scotia Sea). The goals of the study are to determine the imprint of the inflow of deep Antarctic water masses from the Weddell Sea into the Scotia Sea, to establish the factors driving the styles of contourite deposition and to discern the relative contribution of alongslope versus downslope processes to the construction of the uppermost late Quaternary sedimentary record in the basin. The most significant morpho-sedimentary features in Dove Basin are linked to contouritic processes and to mass movements. Plastered drifts on the flanks of the basin constitute the most common contouritic deposits. Basement-controlled drifts on top of structural elevations are common along the central ridge, the central basin plain and scattered along the basin flanks. Sheeted drifts occur on top of adjacent banks or are restricted to the deep basin. In contrast, mounded drifts are poorly represented in Dove basin. A laterally extensive contouritic channel runs along the central ridge. Contouritic channels are also identified in the upper parts of the lateral banks and slopes. Numerous slide scars along the upper parts of the slopes evolve downslope into semitransparent lens-shaped bodies, with occasional development of across-slope channels. Semitransparent lenses occur intercalated within stratified deposits in the slopes of the basin, in the central ridge and in the deepest basin plain. The spatial arrangement of contouritic morphologies points to the influence of the water column structure and the basin physiography. In the eastern sub-basin, two different fractions (lower and upper) of Weddell Sea Deep Water (WSDW) leave an imprint on contourite deposits owing to the sloping interface between the two fractions. Contouritic influence is more subdued in the western sub-basin, and limited to the imprint of the lower WSDW. The upper parts of the surrounding banks are under the influence of deep-reaching Circumpolar waters (i.e., Lower Circumpolar Deep Water), which develops both depositional and erosional morphologies. The cross-section V-shaped morphology of the basin and the common occurrence of structural highs drive the predominance of plastered and basement-controlled drifts in the sediment record. The frequent alternation between contourites and downslope gravity-flow deposits is likely due to different processes associated with over-steepening in the basin, such as basement-controlled steep slopes, deformed drifts atop basement elevations, and the development of thick contouritic piles. Dove Basin is an example of a basin without mounded, plastered or mixed hybrid drifts in the transition between the lower slope and the deep basin, because the upper boundary of the deepest water mass —the Weddell Sea Deep Water— flows shallower along the middle slope. This fact underlines the relevance of the position and depth of water masses in shaping the morphology of the feet of slopes along continental margins. • Late Quaternary contourite deposits in Dove Basin show asymmetric distribution. • Sloping interfases and structure of water masses determine the dominant contouritic drifts. • Influence of basin physiography resulted in widespread plastered and tectonically-driven drifts. • Interactions between contouritic processes and mass movements driven by oversteepening and seismic activity. [ABSTRACT FROM AUTHOR]

Published

2021