Your search keyword '"Peyve, A. A."' showing total 7 results

1. Ultra-depleted melt refertilization of mantle peridotites in a large intra-transform domain (Doldrums Fracture Zone; 7–8°N, Mid Atlantic Ridge)

Author

Sani, Camilla, Sanfilippo, Alessio, Ferrando, Carlotta, Peyve, Alexander A., Skolotonev, Sergey G., Muccini, Filippo, Zanetti, Alberto, Basch, Valentin, Palmiotto, Camilla, Bonatti, Enrico, Ligi, Marco, Sani, Camilla, Sanfilippo, Alessio, Ferrando, Carlotta, Peyve, Alexander A., Skolotonev, Sergey G., Muccini, Filippo, Zanetti, Alberto, Basch, Valentin, Palmiotto, Camilla, Bonatti, Enrico, and Ligi, Marco

Abstract

The Doldrums transform system offsets the Equatorial Mid Atlantic Ridge by ~630 km at 7–8° N. This transform system consists of four intra-transform spreading centers (ITRs) bounded by five transform faults. The northernmost ITR is linked to the MAR axis by a ~ 180 km-long transform. Here, during two R/V A. N. Strakhov expeditions (S06 and S09), mantle peridotites were dredged along the transverse and median ridge of the transform, across the western flank of the ITR valley. Residual harzburgites were mainly sampled along the northern Doldrums transform valley, whereas plagioclase-bearing peridotites showing evidence for melt-rock interaction characterize the ITR domain. Petrological and geochemical observations reinforced by geochemical modelling are used to define the behaviour of trace elements during melt extraction and melt-rock reaction in our rocks. Results suggest that residual peridotites derive from mantle rocks that have undergone a degree of partial melting up to 12%, with melting likely starting at the transition of garnet-spinel stability fields, whereas peridotites which suffered melt-rock reactions have been divided into two types: (i) pl-impregnated peridotites, formed by migration of melts at high porosity and high melt-rock ratio; and (ii) refertilized peridotites, generated at reduced porosity, when small fractions of the same percolating melt crystallized clinopyroxene and minor plagioclase. We suggest that the refertilizing agent was a melt highly depleted in incompatible trace elements, in turn produced by an ultra-depleted mantle source. This mantle experienced previous degrees of melt extraction at the ridge axis, before being transposed laterally along the transform where it melted a second time during the opening of the intra-transform spreading segment.

Published

2020

2. Ultra-depleted melt refertilization of mantle peridotites in a large intra-transform domain (Doldrums Fracture Zone; 7–8°N, Mid Atlantic Ridge)

Author

Sani, Camilla, Sanfilippo, Alessio, Ferrando, Carlotta, Peyve, Alexander A., Skolotonev, Sergey G., Muccini, Filippo, Zanetti, Alberto, Basch, Valentin, Palmiotto, Camilla, Bonatti, Enrico, Ligi, Marco, Sani, Camilla, Sanfilippo, Alessio, Ferrando, Carlotta, Peyve, Alexander A., Skolotonev, Sergey G., Muccini, Filippo, Zanetti, Alberto, Basch, Valentin, Palmiotto, Camilla, Bonatti, Enrico, and Ligi, Marco

Abstract

The Doldrums transform system offsets the Equatorial Mid Atlantic Ridge by ~630 km at 7–8° N. This transform system consists of four intra-transform spreading centers (ITRs) bounded by five transform faults. The northernmost ITR is linked to the MAR axis by a ~ 180 km-long transform. Here, during two R/V A. N. Strakhov expeditions (S06 and S09), mantle peridotites were dredged along the transverse and median ridge of the transform, across the western flank of the ITR valley. Residual harzburgites were mainly sampled along the northern Doldrums transform valley, whereas plagioclase-bearing peridotites showing evidence for melt-rock interaction characterize the ITR domain. Petrological and geochemical observations reinforced by geochemical modelling are used to define the behaviour of trace elements during melt extraction and melt-rock reaction in our rocks. Results suggest that residual peridotites derive from mantle rocks that have undergone a degree of partial melting up to 12%, with melting likely starting at the transition of garnet-spinel stability fields, whereas peridotites which suffered melt-rock reactions have been divided into two types: (i) pl-impregnated peridotites, formed by migration of melts at high porosity and high melt-rock ratio; and (ii) refertilized peridotites, generated at reduced porosity, when small fractions of the same percolating melt crystallized clinopyroxene and minor plagioclase. We suggest that the refertilizing agent was a melt highly depleted in incompatible trace elements, in turn produced by an ultra-depleted mantle source. This mantle experienced previous degrees of melt extraction at the ridge axis, before being transposed laterally along the transform where it melted a second time during the opening of the intra-transform spreading segment.

Published

2020

3. Postglacial paleoceanography of the northwestern Barents Sea

Author

Ivanova, E., Murdmaa, I. O., de Vernal, A., Risebrobakken, B., Hillare-Marcel, C., Brice, C., Peyve, A., Seitkalieva, E., Pisarev, S., Ivanova, E., Murdmaa, I. O., de Vernal, A., Risebrobakken, B., Hillare-Marcel, C., Brice, C., Peyve, A., Seitkalieva, E., and Pisarev, S.

Published

2016

4. First results of cruise S19 (PRIMAR Project): petrological and structural investigations of the Vema Transverse Ridge (equatorial Atlantic)

Author

Fabretti, Paola, Bonatti, Enrico, Peyve, Alexander, Brunelli, Daniele, Cipriani, Anna, Dobrolubova, Xenia, Efimov, Vladimir, Erofeev, Sergej, Gasperini, Luca, Hanley, Jean E., Ligi, Marco, Perfiliev, Andrey, Rastorguyev, Vladimir, Raznitsin, Yurj, Savelieva, Galina, Senjenov, Victor, Simonov, Vladimir, Sokolov, Sergej, Skolotnev, Sergej, Susini, Sara, Vikentyev, Ilya, Fabretti, Paola, Bonatti, Enrico, Peyve, Alexander, Brunelli, Daniele, Cipriani, Anna, Dobrolubova, Xenia, Efimov, Vladimir, Erofeev, Sergej, Gasperini, Luca, Hanley, Jean E., Ligi, Marco, Perfiliev, Andrey, Rastorguyev, Vladimir, Raznitsin, Yurj, Savelieva, Galina, Senjenov, Victor, Simonov, Vladimir, Sokolov, Sergej, Skolotnev, Sergej, Susini, Sara, and Vikentyev, Ilya

Abstract

We carried out in January-March 1998 a geological-geophysical cruise to the Vema fracture zone that offsets by 320 km the Mid Atlantic Ridge in the central Atlantic. This expedition (S19) was part of PRIMAR (Russian-Italian Mid Atlantic Ridge Project). The field work aimed at obtaining geophysical and petrological data from a prominent transverse ridge that runs on the southern side of the transform valley and constitutes a major topographic anomaly relative to the depth/square root of age relationship. Previous work had shown that a relatively undisturbed section of oceanic lithosphere is exposed on the northern side of the transverse ridge for roughly 270 km along a seafloor spreading flow line. Given an average spreading half rate of 16 mm/y, this length corresponds to over 16 My. One of the objectives of our expedition was to sample at close-spaced (~ 5 km) horizontal intervals the mantle ultramafic basal unit, in order to detect temporal variations of mantle composition and of accretion processes at ridge axis. Preliminary observations on ultramafic rock samples obtained at 35 sites suggest strong temporal variations of mantle structure and composition. Multichannel seismic reflection profiles were carried out in order to understand the processes that uplifted the transverse ridge and exposed the sliver of oceanic lithosphere. Magnetometric profiles were made to better constrain spreading rates.

Published

1998

5. First results of cruise S19 (PRIMAR Project): petrological and structural investigations of the Vema Transverse Ridge (equatorial Atlantic)

Author

Fabretti, Paola, Bonatti, Enrico, Peyve, Alexander, Brunelli, Daniele, Cipriani, Anna, Dobrolubova, Xenia, Efimov, Vladimir, Erofeev, Sergej, Gasperini, Luca, Hanley, Jean E., Ligi, Marco, Perfiliev, Andrey, Rastorguyev, Vladimir, Raznitsin, Yurj, Savelieva, Galina, Senjenov, Victor, Simonov, Vladimir, Sokolov, Sergej, Skolotnev, Sergej, Susini, Sara, Vikentyev, Ilya, Fabretti, Paola, Bonatti, Enrico, Peyve, Alexander, Brunelli, Daniele, Cipriani, Anna, Dobrolubova, Xenia, Efimov, Vladimir, Erofeev, Sergej, Gasperini, Luca, Hanley, Jean E., Ligi, Marco, Perfiliev, Andrey, Rastorguyev, Vladimir, Raznitsin, Yurj, Savelieva, Galina, Senjenov, Victor, Simonov, Vladimir, Sokolov, Sergej, Skolotnev, Sergej, Susini, Sara, and Vikentyev, Ilya

Abstract

We carried out in January-March 1998 a geological-geophysical cruise to the Vema fracture zone that offsets by 320 km the Mid Atlantic Ridge in the central Atlantic. This expedition (S19) was part of PRIMAR (Russian-Italian Mid Atlantic Ridge Project). The field work aimed at obtaining geophysical and petrological data from a prominent transverse ridge that runs on the southern side of the transform valley and constitutes a major topographic anomaly relative to the depth/square root of age relationship. Previous work had shown that a relatively undisturbed section of oceanic lithosphere is exposed on the northern side of the transverse ridge for roughly 270 km along a seafloor spreading flow line. Given an average spreading half rate of 16 mm/y, this length corresponds to over 16 My. One of the objectives of our expedition was to sample at close-spaced (~ 5 km) horizontal intervals the mantle ultramafic basal unit, in order to detect temporal variations of mantle composition and of accretion processes at ridge axis. Preliminary observations on ultramafic rock samples obtained at 35 sites suggest strong temporal variations of mantle structure and composition. Multichannel seismic reflection profiles were carried out in order to understand the processes that uplifted the transverse ridge and exposed the sliver of oceanic lithosphere. Magnetometric profiles were made to better constrain spreading rates.

Published

1998

6. Transform migration and vertical tectonics at the Romanche fracture zone, equatorial Atlantic

Author

Bonatti, E., Ligi, M., Gasperini, L., Peyve, A., Raznitsin, Y., Chen, Y. J., Bonatti, E., Ligi, M., Gasperini, L., Peyve, A., Raznitsin, Y., and Chen, Y. J.

Abstract

The Romanche transform offsets the Mid‐Atlantic Ridge (MAR) axis by about 950 km in the equatorial Atlantic. Multibeam and high‐resolution multichannel seismic reflection surveys as well as rock sampling were carried out on the eastern part of the transform with the R/V Akademik Strakhov as part of the Russian‐Italian Mid‐Atlantic Ridge Project (PRIMAR). Morphobathymetric data show the existence on the northern side of the transform of a major 800‐km‐long aseismic valley oriented 10° to 15° from the active valley; it disappears about 150 km from the western MAR segment. The aseismic valley marks probably the former location of the Romanche transform (“PaleoRomanche”) that was active up to roughly 8–10 Ma, when the transform boundary migrated to its present position. A temporary microplate developed during the migration and reorientation of the transform. This microplate changed its sense of motion as it was transferred from the South American to the African plate. A prominent transverse ridge extends for several hundred kilometers parallel to the transform on its northern side, reaching its shallowest part (shallower by over 4 km than the predicted thermal contraction depth) in a zone opposite the eastern MAR axis/transform intersection (RTI). Flat‐top peaks on the summit of the transverse ridge are capped by acoustically transparent, weakly stratified, shallow water platfonn/lagunal/reef limestones. This limestone unit is a few hundred meters thick and overlies igneous basement. Evaluation of the seismic reflection data as well as study of samples of carbonates, ventifact basaltic pebbles and gabbroic, peridotitic and basaltic rocks recovered at different sites on the transverse ridge, suggest that (1) the summit of the transverse ridge was above sea level at and before about 5 Ma; (2) the transverse ridge subsided since then at an average rate 1 order of magnitude faster than the predicted thermal contraction rate; its summit was flattened by erosion at sea level

Published

1994

7. Transform migration and vertical tectonics at the Romanche fracture zone, equatorial Atlantic

Author

Bonatti, E., Ligi, M., Gasperini, L., Peyve, A., Raznitsin, Y., Chen, Y. J., Bonatti, E., Ligi, M., Gasperini, L., Peyve, A., Raznitsin, Y., and Chen, Y. J.

Abstract

The Romanche transform offsets the Mid‐Atlantic Ridge (MAR) axis by about 950 km in the equatorial Atlantic. Multibeam and high‐resolution multichannel seismic reflection surveys as well as rock sampling were carried out on the eastern part of the transform with the R/V Akademik Strakhov as part of the Russian‐Italian Mid‐Atlantic Ridge Project (PRIMAR). Morphobathymetric data show the existence on the northern side of the transform of a major 800‐km‐long aseismic valley oriented 10° to 15° from the active valley; it disappears about 150 km from the western MAR segment. The aseismic valley marks probably the former location of the Romanche transform (“PaleoRomanche”) that was active up to roughly 8–10 Ma, when the transform boundary migrated to its present position. A temporary microplate developed during the migration and reorientation of the transform. This microplate changed its sense of motion as it was transferred from the South American to the African plate. A prominent transverse ridge extends for several hundred kilometers parallel to the transform on its northern side, reaching its shallowest part (shallower by over 4 km than the predicted thermal contraction depth) in a zone opposite the eastern MAR axis/transform intersection (RTI). Flat‐top peaks on the summit of the transverse ridge are capped by acoustically transparent, weakly stratified, shallow water platfonn/lagunal/reef limestones. This limestone unit is a few hundred meters thick and overlies igneous basement. Evaluation of the seismic reflection data as well as study of samples of carbonates, ventifact basaltic pebbles and gabbroic, peridotitic and basaltic rocks recovered at different sites on the transverse ridge, suggest that (1) the summit of the transverse ridge was above sea level at and before about 5 Ma; (2) the transverse ridge subsided since then at an average rate 1 order of magnitude faster than the predicted thermal contraction rate; its summit was flattened by erosion at sea level

Published

1994