Your search keyword '"Valle, G. Dalla"' showing total 7 results

1. Nature and Origin of Magnetic Lineations Within Valdivia Bank: Ocean Plateau Formation by Complex Seafloor Spreading

Author

Thoram, S., primary, Sager, W. W., additional, Gaastra, K., additional, Tikoo, S. M., additional, Carvallo, C., additional, Avery, A., additional, Del Gaudio, Arianna V., additional, Huang, Y., additional, Hoernle, K., additional, Höfig, T. W., additional, Bhutani, R., additional, Buchs, D. M., additional, Class, C., additional, Dai, Y., additional, Valle, G. Dalla, additional, Fielding, S., additional, Han, S., additional, Heaton, D. E., additional, Homrighausen, S., additional, Kubota, Y., additional, Li, C.‐F., additional, Nelson, W. R., additional, Petrou, E., additional, Potter, K. E., additional, Pujatti, S., additional, Scholpp, J., additional, Shervais, J. W., additional, Tshiningayamwe, M., additional, Wang, X. J., additional, and Widdowson, M., additional

Published

2023

2. Site U1578.

Author

Sager, W., Hoernle, K., Höfig, T. W., Avery, A. J., Bhutani, R., Buchs, D. M., Carvallo, C. A., Class, C., Dai, Y., Valle, G. Dalla, Del Gaudio, A. V., Fielding, S., Gaastra, K. M., Han, S., Homrighausen, S., Kubota, Y., Li, C.-F., Nelson, W. R., Petrou, E., and Potter, K. E.

Subjects

SHEAR waves, INTERTIDAL zonation, LAVA flows, OBSIDIAN, PHENOCRYSTS

Published

2023

3. Expedition 391 summary.

Author

Sager, W., Hoernle, K., Höfig, T. W., Avery, A. J., Bhutani, R., Buchs, D. M., Carvallo, C. A., Class, C., Dai, Y., Valle, G. Dalla, Del Gaudio, A. V., Fielding, S., Gaastra, K. M., Han, S., Homrighausen, S., Kubota, Y., Li, C.-F., Nelson, W. R., Petrou, E., and Potter, K. E.

Subjects

SEAMOUNTS, GEODYNAMICS, INTERTIDAL zonation, COVID-19 pandemic, SEDIMENTS

Abstract

Hotspot tracks (chains of seamounts, ridges, and other volcanic structures) provide important records of plate motions, as well as mantle geodynamics, magma flux, and mantle source compositions. The Tristan-Gough-Walvis Ridge (TGW) hotspot track, extending from the active volcanic islands of Tristan da Cunha and Gough through a province of guyots and then along Walvis Ridge to the Etendeka flood basalt province, forms one of the most prominent and complex global hotspot tracks. The TGW hotspot track displays a tight linear age progression in which ages increase from the islands to the flood basalts (covering ~135 My). Unlike Pacific tracks, which are often simple, nearly linear chains of seamounts, the TGW track is alternately a steep-sided narrow ridge, an oceanic plateau, subparallel linear ridges and chains of seamounts (most are flat-topped guyots). The track displays isotopic zonation over the last ~70 My. The zonation appears near the middle of the track just before it splits into two to three chains of ridge- and guyot-type seamounts. Walvis Ridge, forming the older part of the track, is also overprinted with age-progressive late-stage volcanism, which was emplaced ~30-40 My after the initial eruptions and has a distinct isotopic composition. The plan for Expedition 391 was to drill at six sites, three along Walvis Ridge and three in the seamounts of the Guyot Province, to collect igneous rocks to better understand the formation of volcanic edifices, the temporal and geochemical evolution of the hotspot, and the variation in paleolatitudes at which the volcanic edifices formed. After a delay of 18 days to address a shipboard Coronavirus (COVID-19) outbreak, Expedition 391 proceeded to drill at four of the proposed sites: three sites on Walvis Ridge around Valdivia Bank, an ocean plateau within the ridge, and one site on the lower flank of a guyot in the Center track of the Guyot Province, a ridge located between the Tristan subtrack (which extends from the end of Walvis Ridge to the islands of Tristan da Cunha) and the Gough subtrack (which extends from Walvis Ridge to Gough Island). The first hole was drilled at Site U1575, located on a low portion of the northeastern Walvis Ridge just north of Valdivia Bank. At this location, 209.9 m of sediments and 122.4 m of igneous basement were cored. The sediments ranged in age from Late Pleistocene (~0.43-1.24 Ma) to Late Cretaceous (Campanian; 72-78 Ma). The igneous basement comprised 10 submarine lava units consisting of pillow, lobate, sheet, and massive lava flows, the thickest of which was ~21 m. Most lavas are tholeiitic, but some alkalic basalts were recovered. A portion of the igneous succession consists of low-Ti basalts, which are unusual because they appear in the Etendeka flood basalts but have not been previously found on Walvis Ridge. Two holes were drilled at Site U1576 on the west flank of Valdivia Bank. The first of these holes was terminated because a bit jammed shortly after entering the igneous basement. Hole U1576A recovered a remarkable ~380 m thick sedimentary section consisting mostly of chalk covering a nearly complete sequence from Late Pleistocene (~0.43-1.24 Ma) to Late Cretaceous (Campanian; ~79-81.38 Ma). These sediments display short and long cyclic color changes that imply astronomically forced and longer term paleoenvironmental changes. The igneous basement recovered in Hole U1576B yielded 11 submarine lava units (total thickness = ~65 m). The flows range from pillows to massive flows with compositions varying from tholeiitic basalt to basaltic andesite, only the second occurrence of the latter composition recovered from the TGW track thus far. These units are separated by seven sedimentary chalk units that range 0.1-11.6 m in thickness, implying a longterm interplay of sedimentation and lava eruptions. These intercalated sediments revealed Upper Cretaceous (Campanian) ages of ~77-79 Ma for the upper two interbeds and ~79-81.38 Ma for the lower beds. Coring at Site U1577, on the extreme eastern flank of Valdivia Bank, penetrated a 154.8 m thick sedimentary section ranging from the Paleocene (Thanetian; ~58.8 Ma) to Upper Cretaceous (Campanian; ~81.43-83.20 Ma). Igneous basement coring progressed only 39.1 m below the sediment/basalt contact, recovering three massive submarine tholeiitic basalt lava flows that are 4.1, 15.5, and >19.1 m thick, respectively. Paleomagnetic data from Sites U1577 and U1576 indicate that the former volcanic basement formed just before the end of the Cretaceous Normal Superchron and the latter during Chron 33r, shortly afterward. Biostratigraphic and paleomagnetic data suggest that Valdivia Bank becomes younger from east to west. Site U1578, located on a Center track guyot, provided a long and varied igneous section. After coring through 184.3 m of pelagic carbonate sediments mainly consisting of Eocene and Paleocene chalk (~55.64-63.5 Ma), Hole U1578A cored 302.1 m of igneous basement. Basement lavas are largely pillows but are interspersed with sheet and massive flows. Lava compositions are mostly alkalic basalts with some hawaiite. Several intervals contain abundant olivine (some fresh), and some of the pillow stacks consist of basalt with remarkably high Ti content. The igneous sequence is interrupted by 10 sedimentary interbeds consisting of chalk and volcaniclastics and ranging 0.46-10.19 m in thickness. Investigations of toothpick samples from the intercalated sediments were examined, each revealing the same age range of ~63.5-64.81 Ma (lower Paleocene; Danian). Paleomagnetic data display a change in basement magnetic polarity ~100 m above the base of the hole. Combining magnetic stratigraphy with biostratigraphic data, the igneous section is inferred to span >1 My.** Nearly 7 months after Expedition 391, JOIDES Resolution transited from Cape Town to the north Atlantic. During this transit (Expedition 397T), 7.9 days of ship time were used to drill two holes (U1584A and U1585A) at sites on the Gough and Tristan tracks that had been omitted because of COVID-19-related time loss on the earlier cruise. For both, coring was begun only a short distance above the igneous basement to save time. The 75.2 m thick section drilled in Hole U1584A contains two sedimentary units: clay-rich carbonate sediments overlie a pumice-dominated volcaniclastic deposit containing basalt fragments. Because the goal was to core basalt and the base of the volcaniclastic deposit was not imaged in the seismic profile, the hole was terminated early to save operation time for the next site. In Hole U1585A, coring penetrated a 273.5 m thick sediment section overlying an 81.2 m thick pile of massive basalt flows. The sediment section is divided into four units: • The uppermost unit consists of nannofossil chalk; • The two intermediate units contain alternating chalk and volcaniclastic sediments containing several breccia units; and • The lowermost unit consists of volcanic breccia containing juvenile blocks, bombs, and accretionary lapilli. This thick sedimentary section documents a transition from shallow-water volcanism to openocean sedimentation as the seamount subsided. The thick underlying basalt section is made up of four sparsely to highly phyric massive flows, the thickest of which is >43 m thick. Samples of these units are mostly basalt with a few trachybasalts and one trachyandesite. Although the igneous penetration was less than planned, coring during Expeditions 391 and 397T obtained samples that clearly will lead to an improved understanding of the evolution of the TGW hotspot and its track. Reasonable recovery of fresh basalt in some holes provides ample samples for geochemical, geochronologic, and paleomagnetic studies. Good recovery of Late Cretaceous and early Cenozoic chalk successions provides samples for paleoenvironmental study. [ABSTRACT FROM AUTHOR]

Published

2023

4. Expedition 391 methods.

Author

Sager, W., Hoernle, K., Höfig, T. W., Avery, A. J., Bhutani, R., Buchs, D. M., Carvallo, C. A., Class, C., Dai, Y., Valle, G. Dalla, Del Gaudio, A. V., Fielding, S., Gaastra, K. M., Han, S., Homrighausen, S., Kubota, Y., Li, C.-F., Nelson, W. R., Petrou, E., and Potter, K. E.

Subjects

SHEAR waves, INTERNAL friction, INTERTIDAL zonation

Published

2023

5. Morphology of late Quaternary mass-transport complexes along the South-Western Adriatc Margin

Author

Valle, G. Dalla, primary, Campiani, E., additional, Foglini, F., additional, Gamberi, F., additional, Maselli, V., additional, Pellegrini, C., additional, and Trincardi, F., additional

Published

2018

6. Nature and Origin of Magnetic Lineations Within Valdivia Bank: Ocean Plateau Formation by Complex Seafloor Spreading

Author

Thoram, S., Sager, W. W., Gaastra, K., Tikoo, S. M., Carvallo, C., Avery, A., Del Gaudio, Arianna V., Huang, Y., Hoernle, Kaj, Höfig, T. W., Bhutani, R., Buchs, D. M., Class, C., Dai, Y., Valle, G. Dalla, Fielding, S., Han, S., Heaton, D. E., Homrighausen, S., Kubota, Y., Li, C.‐F., Nelson, W. R., Petrou, E., Potter, K. E., Pujatti, S., Scholpp, J., Shervais, J. W., Tshiningayamwe, M., Wang, X. J., Widdowson, M., Thoram, S., Sager, W. W., Gaastra, K., Tikoo, S. M., Carvallo, C., Avery, A., Del Gaudio, Arianna V., Huang, Y., Hoernle, Kaj, Höfig, T. W., Bhutani, R., Buchs, D. M., Class, C., Dai, Y., Valle, G. Dalla, Fielding, S., Han, S., Heaton, D. E., Homrighausen, S., Kubota, Y., Li, C.‐F., Nelson, W. R., Petrou, E., Potter, K. E., Pujatti, S., Scholpp, J., Shervais, J. W., Tshiningayamwe, M., Wang, X. J., and Widdowson, M.

Abstract

Valdivia Bank (VB) is a Late Cretaceous oceanic plateau formed by volcanism from the Tristan-Gough hotspot at the Mid-Atlantic Ridge (MAR). To better understand its origin and evolution, magnetic data were used to generate a magnetic anomaly grid, which was inverted to determine crustal magnetization. The magnetization model reveals quasi-linear polarity zones crossing the plateau and following expected MAR paleo-locations, implying formation by seafloor spreading over ∼4 Myr during the formation of anomalies C34n-C33r. Paleomagnetism and biostratigraphy data from International Ocean Discovery Program Expedition 391 confirm the magnetic interpretation. Anomaly C33r is split into two negative bands, likely by a westward ridge jump. One of these negative anomalies coincides with deep rift valleys, indicating their age and mechanism of formation. These findings imply that VB originated by seafloor spreading-type volcanism during a plate reorganization, not from a vertical stack of lava flows as expected for a large volcano. Key Points - Valdivia Bank is characterized by quasi-linear magnetic anomalies that are parallel to the inferred paleo-Mid-Atlantic Ridge - Magnetic anomalies imply that the plateau becomes younger E-W consistent with formation via seafloor spreading during anomalies C34n-C33r - Rift valleys, division of C33r, and anomaly curvature imply complex ridge tectonics and a ridge jump

Published

2023

7. Large-scale response of the Eastern Mediterranean thermohaline circulation to African monsoon intensification during sapropel S1 formation

Author

Tesi, T., Asioli, A., Minisini, D., Maselli, V., Valle, G. Dalla, Gamberi, F., Langone, L., Cattaneo, Antonio, Montagna, P., Trincardi, F., Tesi, T., Asioli, A., Minisini, D., Maselli, V., Valle, G. Dalla, Gamberi, F., Langone, L., Cattaneo, Antonio, Montagna, P., and Trincardi, F.

Abstract

The formation of Eastern Mediterranean sapropels has periodically occurred during intensification of northern hemisphere monsoon precipitation over North Africa. However, the large-scale response of the Eastern Mediterranean thermohaline circulation during these monsoon-fuelled freshening episodes is poorly constrained. Here, we investigate the formation of the youngest sapropel (S1) along an across-slope transect in the Adriatic Sea. Foraminifera-based oxygen index, redox-sensitive elements and biogeochemical parameters reveal – for the first time – that the Adriatic S1 was synchronous with the deposition of south-eastern Mediterranean S1 beds. Proxies of paleo thermohaline currents indicate that the bottom-hugging North Adriatic Dense Water (NAdDW) suddenly decreased at the sapropel onset simultaneously with the maximum freshening of the Levantine Sea during the African Humid Period. We conclude that the lack of the “salty” Levantine Intermediate Water hampered the preconditioning of the northern Adriatic waters necessary for the NAdDW formation prior to the winter cooling. Consequently, a weak NAdDW limited in turn the Eastern Mediterranean Deep Water (EMDWAdriatic) formation with important consequences for the ventilation of the Ionian basin as well. Our results highlight the importance of the Adriatic for the deep water ventilation and the interdependence among the major eastern Mediterranean water masses whose destabilization exerted first-order control on S1 deposition.

Published

2017