Your search keyword '"Hernández-Molina, Francisco J."' showing total 8 results

1. Secondary flow in contour currents controls the formation of moat-drift contourite systems

Author

University of Bremen, Royal Holloway, University of London, Projekt DEAL, Wilckens, Henriette, Eggenhuisen, Joris T., Adema, Pelle H., Hernández-Molina, Francisco J., Jacinto, Ricardo Silva, Miramontes, Elda, University of Bremen, Royal Holloway, University of London, Projekt DEAL, Wilckens, Henriette, Eggenhuisen, Joris T., Adema, Pelle H., Hernández-Molina, Francisco J., Jacinto, Ricardo Silva, and Miramontes, Elda

Abstract

Ocean currents control seafloor morphology and the transport of sediments, organic carbon, nutrients, and pollutants in deep-water environments. A better connection between sedimentary deposits formed by bottom currents (contourites) and hydrodynamics is necessary to improve reconstructions of paleocurrent and sediment transport pathways. Here we use physical modeling in a three-dimensional flume tank to analyse the morphology and hydrodynamics of a self-emerging contourite system. The sedimentary features that developed on a flat surface parallel to a slope are an elongated depression (moat) and an associated sediment accumulation (drift). The moat-drift system can only form in the presence of a secondary flow near the seafloor that transports sediment from the slope toward the drift. The secondary flow increases with higher speeds and steeper slopes, leading to steeper adjacent drifts. This study shows how bottom currents shape the morphology of the moat-drift system and highlights their potential to estimate paleo-ocean current strength.

Published

2023

2. Generation of Bedforms by the Mediterranean Outflow Current at the Exit of the Strait of Gibraltar

Author

Ercilla, Gemma, Casas, David, Hernández-Molina, Francisco J., Roque, Cristina, Ercilla, Gemma, Casas, David, Hernández-Molina, Francisco J., and Roque, Cristina

Abstract

During the MOWER cruise, an ARGUS remotely operated vehicle (ROV) was used to image the effects of the bottom current dynamics of the Mediterranean Outflow Water (MOW) on the Cadiz contourite depositional system (CDS) (Atlantic Sea), at water depths of 500–700 m just downstream of the Strait of Gibraltar. The new images presented here show both longitudinal and transverse bedforms at different scales that are superimposed and coexist throughout the region. Their spatial distribution suggests a general decrease in the MOW velocity westward and the control of the type of bedforms over short distances by sediments and changing seafloor morphology. The superposition of the bedforms also suggests variability in the strength and direction of the bottom current

Published

2017

3. Deep-water Circulation: Processes & Products (16–18 June 2010, Baiona): introduction and future challenges

Author

Hernández-Molina, Francisco J., Stow, Dorrik A.V., Llave, Estefanía, Rebesco, Michele, Ercilla, Gemma, Van Rooij, D., Mena, Anxo, Vázquez, Juan Tomás, Voelker, Antje H. L., Hernández-Molina, Francisco J., Stow, Dorrik A.V., Llave, Estefanía, Rebesco, Michele, Ercilla, Gemma, Van Rooij, D., Mena, Anxo, Vázquez, Juan Tomás, and Voelker, Antje H. L.

Abstract

Deep-water circulation is a critical part of the global conveyor belt that regulates Earth’s climate. The bottom (contour)-current component of this circulation is of key significance in shaping the deep seafloor through erosion, transport, and deposition. As a result, there exists a high variety of large-scale erosional and depositional features (drifts) that together form more complex contourite depositional systems on continental slopes and rises as well as in ocean basins, generated by different water masses flowing at different depths and at different speeds either in the same or in opposite directions. Yet, the nature of these deep-water processes and the deposited contourites is still poorly understood in detail. Their ultimate decoding will undoubtedly yield information of fundamental importance to the earth and ocean sciences. The international congress Deep-water Circulation: Processes & Products was held from 16–18 June 2010 in Baiona, Spain, hosted by the University of Vigo. Volume 31(5/6) of Geo-Marine Letters is a special double issue containing 17 selected contributions from the congress, guest edited by F.J. Hernández-Molina, D.A.V. Stow, E. Llave, M. Rebesco, G. Ercilla, D. Van Rooij, A. Mena, J.-T. Vázquez and A.H.L. Voelker. The papers and discussions at the congress and the articles in this special issue provide a truly multidisciplinary perspective of interest to both academic and industrial participants, contributing to the advancement of knowledge on deep-water bottom circulation and related processes, as well as contourite sedimentation. The multidisciplinary contributions (including geomorphology, tectonics, stratigraphy, sedimentology, paleoceanography, physical oceanography, and deep-water ecology) have demonstrated that advances in paleoceanographic reconstructions and our understanding of the ocean’s role in the global climate system depend largely on the feedbacks among disciplines. New insights into the link between the biota of deep-w

Published

2011

4. Pliocene-Quaternary contourites along the northern Gulf of Cadiz margin: sedimentary stacking pattern and regional distribution

Author

Llave, Estefanía, Matias, Hugo, Hernández-Molina, Francisco J., Ercilla, Gemma, Stow, Dorrik A.V., Medialdea Cela, Teresa, Llave, Estefanía, Matias, Hugo, Hernández-Molina, Francisco J., Ercilla, Gemma, Stow, Dorrik A.V., and Medialdea Cela, Teresa

Abstract

This study reports novel findings on the Pliocene–Quaternary history of the northern Gulf of Cadiz margin and the spatiotemporal evolution of the associated contourite depositional system. Four major seismic units (P1, P2, QI and QII) were identified in the Pliocene–Quaternary sedimentary record based on multichannel seismic profiles. These are bounded by five major discontinuities which, from older to younger, are the M (Messinian), LPR (lower Pliocene revolution), BQD (base Quaternary discontinuity), MPR (mid-Pleistocene revolution) and the actual seafloor. Unit P1 represents pre-contourite hemipelagic/pelagic deposition along the northern Gulf of Cadiz margin. Unit P2 reflects a significant change in margin sedimentation when contourite deposition started after the Early Pliocene. Mounded elongated and separated drifts were generated during unit QI deposition, accompanied by a general upslope progradation of drifts and the migration of main depocentres towards the north and northwest during both the Pliocene and Quaternary. This progradation became particularly marked during QII deposition after the mid-Pleistocene (MPR). Based on the spatial distribution of the main contourite depocentres and their thickness, three structural zones have been identified: (1) an eastern zone, where NE–SW diapiric ridges have controlled the development of two internal sedimentary basins; (2) a central zone, which shows important direct control by the Guadalquivir Bank in the south and an E–W Miocene palaeorelief structure in the north, both of which have significantly conditioned the basin-infill geometry; and (3) a western zone, affected in the north by the Miocene palaeorelief which favours deposition in the southern part of the basin. Pliocene tectonic activity has been an important factor in controlling slope morphology and, hence, influencing Mediterranean Outflow Water pathways. Since the mid-Pleistocene (MPR), the sedimentary stacking pattern of contourite drifts has been le

Published

2011

5. Along-­slope oceanographic processes and sedimentary products around the Iberian margin

Author

Hernández-Molina, Francisco J., Serra, Nuno, Stow, Dorrik A.V., Llave, Estefanía, Ercilla, Gemma, Van Rooij, D., Hernández-Molina, Francisco J., Serra, Nuno, Stow, Dorrik A.V., Llave, Estefanía, Ercilla, Gemma, and Van Rooij, D.

Abstract

This contribution to this special volume represents the first attempt to comprehensively describe regional contourite (along-slope) processes and their sedimentary impacts around the Iberian margin, combining numerically simulated bottom currents with existing knowledge of contourite depositional and erosional features. The circulation of water masses is correlated with major contourite depositional systems (CDSs), and potential areas where new CDSs could be found are identified. Water-mass circulation leads to the development of along-slope currents which, in turn, generate contourite features comprising individual contourite drifts and erosional elements forming extensive, complex CDSs of considerable thickness in various geological settings. The regionally simulated bottom-current velocities reveal the strong impact of these water masses on the seafloor, especially in two principal areas: (1) the continental slopes of the Alboran Sea and the Atlantic Iberian margins, and (2) the abyssal plains in the Western Mediterranean and eastern Atlantic. Contourite processes at this scale are associated mainly with the Western Mediterranean Deep Water and the Levantine Intermediate Water in the Alboran Sea, and with both the Mediterranean Outflow Water and the Lower Deep Water in the Atlantic. Deep gateways are essential in controlling water-mass exchange between the abyssal plains, and thereby bottom-current velocities and pathways. Seamounts represent important obstacles for water-mass circulation, and high bottom-current velocities are predicted around their flanks, too. Based on these findings and those of a selected literature review, including less easily accessible “grey literature” such as theses and internal reports, it is clear that the role of bottom currents in shaping continental margins and abyssal plains has to date been generally underestimated, and that many may harbour contourite systems which still remain unexplored today. CDSs incorporate valuable sedime

Published

2011

6. Growth patterns of a proximal terrigenous margin offshore the Guadalfeo River, northern Alboran Sea (SW Mediterranean Sea): glacio-eustatic control and disturbing tectonic factors

Author

Lobo, F. J., Maldonado, Andrés, Hernández-Molina, Francisco J., Fernández-Salas, L. M., Ercilla, Gemma, Alonso, Belén, Lobo, F. J., Maldonado, Andrés, Hernández-Molina, Francisco J., Fernández-Salas, L. M., Ercilla, Gemma, and Alonso, Belén

Abstract

The shelf-upper slope stratigraphy offshore and around the Guadalfeo River on the northern continental margin of the Alboran Sea, Western Mediterranean Basin, has been defined through the interpretation of a grid of Sparker seismic profiles. We tried to identify evolutionary trends in shelf growth, as well as to determine the regional/local factors that may modify the influence of glacio-eustatic fluctuations. Four major depositional sequences are identified in the sedimentary record by a detailed seismic interpretation, which defines three significant intervals of shelf-upper slope progradation, dominated by deposition of shelf-margin wedges, which resulted in uniform patterns of shelf-margin growth in response to significant sea-level falls. In contrast, the record of transgressive intervals is more variable, mainly as the result of distinct patterns of regressive-to-transgressive transitions. Major progradational wedges are internally composed of seaward-prograding, landward-thinning wedges, interpreted to represent shelf-margin deltaic deposits. In contrast, the last aggradational interval is composed of shelf-prograding wedges that show distinct characteristics, in terms of seismic facies, morphology and distribution when compared with previous shelf-margin wedges. These shelf wedges are thought to represent the particular case of Regressive Systems or Shelf Margin Systems Tracts, and their development seems to be controlled by a drastic change in main depocenter location, which moved from the upper slope to the shelf during the Pleistocene. The stacking pattern of seismic units, the shallowness of the acoustic basement and the migration of the shelf break are used to infer spatial and temporal changes in tectonic subsidence-uplift rates, which interact with low-order glacio-eustatic changes. For much of the Pliocene-Quaternary, uplifted sectors alternated laterally with sectors experiencing more subsidence. Subsequently, a significant change from lateral outgr

Published

2008

7. Seismic Stratigraphy of Miocene to Recent Sedimentary Deposits in the Central Scotia Sea and Northern Weddell Sea: Influence of Bottom Flows (Antarctica)

Author

Maldonado, Andrés, Barnolas Cortina, Antonio, Bohoyo, Fernando, Carlota Escutia, Carlta, Galindo-Zaldívar, Jesús, Hernández-Molina, Francisco J., Jabaloy, Antonio, Lobo, F. J., Nelson, C. Hans, Rodríguez-Fernández, José, Somoza, Luis, Suriñach, Emma, Vázquez, Juan Tomás, Maldonado, Andrés, Barnolas Cortina, Antonio, Bohoyo, Fernando, Carlota Escutia, Carlta, Galindo-Zaldívar, Jesús, Hernández-Molina, Francisco J., Jabaloy, Antonio, Lobo, F. J., Nelson, C. Hans, Rodríguez-Fernández, José, Somoza, Luis, Suriñach, Emma, and Vázquez, Juan Tomás

Abstract

Multichannel and high resolution seismic profiles from the central Scotia Sea and northern Weddell Sea show a sequence of seismic units interpreted to be the result of high-energy bottom currents. The seismic character of the units is indicative of active bottom flows, which developed extensive drifts under the influence of the Weddell Sea Bottom Water (WSBW) and the Antarctic Circumpolar Current (ACC). The opening of the connection between Jane Basin and the Scotia Sea is marked by a major regional unconformity that recorded a reorganization of bottom flows. The uppermost deposits are characterized by intensified bottom currents, which may reflect increased production of WSBW.

Published

2006

8. Ocean basins near the Scotia–Antarctic plate boundary: Influence of tectonics and paleoceanography on the Cenozoic deposits

Author

Maldonado, Andrés, Bohoyo, Fernando, Galindo-Zaldívar, Jesús, Hernández-Molina, Francisco J., Jabaloy, Antonio, Lobo, F. J., Rodríguez-Fernández, José, Suriñach, Emma, Vázquez, Juan Tomás, Maldonado, Andrés, Bohoyo, Fernando, Galindo-Zaldívar, Jesús, Hernández-Molina, Francisco J., Jabaloy, Antonio, Lobo, F. J., Rodríguez-Fernández, José, Suriñach, Emma, and Vázquez, Juan Tomás

Abstract

The distribution of seismic units in deposits of the basins near the Antarctic–Scotia plate boundary is described based on the analysis of multichannel seismic reflection profiles. Five main seismic units are identified. The units are bounded by high-amplitude continuous reflectors, named a to d from top to bottom. The two older units are of different age and seismic facies in each basin and were generally deposited during active rifting and seafloor spreading. The three youngest units (3 to 1) exhibit, in contrast, rather similar seismic facies and can be correlated at a regional scale. The deposits are types of contourite drift that resulted from the interplay between the northeastward flow of Weddell Sea Bottom Water (WSBW) and the complex bathymetry in the northern Weddell Sea, and from the influence of the Antarctic Circumpolar Current and the WSBW in the Scotia Sea. A major paleoceanographic event was recorded by Reflector c, during the Middle Miocene, which represents the connection between the Scotia Sea and the Weddell Sea after the opening of Jane Basin. Unit 3 (tentatively dated ∼Middle to Late Miocene) shows the initial incursions of the WSBW into the Scotia Sea, which influenced a northward progradational pattern, in contrast to the underlying deposits. The age attributed to Reflector b is coincident with the end of spreading at the West Scotia Ridge (∼6.4 Ma). Unit 2 (dated ∼Late Miocene to Early Pliocene) includes abundant high-energy, sheeted deposits in the northern Weddell Sea, which may reflect a higher production of WSBW as a result of the advance of the West Antarctic ice-sheet onto the continental shelf. Reflector a represents the last major regional paleoceanographic change. The timing of this event (∼3.5–3.8 Ma) coincides with the end of spreading at the Phoenix–Antarctic Ridge, but may be also correlated with global events such as initiation of the permanent Northern Hemisphere ice-sheet and a major sea level drop. Unit 1 (dated ∼Late Plioce

Published

2006