Your search keyword '"Sayol España, J.M. (author)"' showing total 13 results

1. Direct and Indirect Pathways of Convected Water Masses and Their impacts on the Overturning Dynamics of the Labrador Sea

Author

Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), van der Boog, C.G. (author), Spence, P. (author), Pietrzak, J.D. (author), Katsman, C.A. (author), Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), van der Boog, C.G. (author), Spence, P. (author), Pietrzak, J.D. (author), and Katsman, C.A. (author)

Abstract

The dense waters formed by wintertime convection in the Labrador Sea play a key role in setting the properties of the deep Atlantic Ocean. To understand how variability in their production might affect the Atlantic Meridional Overturning Circulation (AMOC) variability, it is essential to determine pathways and associated timescales of their export. In this study, we analyze the trajectories of Argo floats and of Lagrangian particles launched at 53°N in the boundary current and traced backward in time in a high-resolution model, to identify and quantify the importance of upstream pathways. We find that 85% of the transport carried by the particles at 53°N originates from Cape Farewell, and it is split between a direct route that follows the boundary current and an indirect route involving boundary-interior exchanges. Although both routes contribute roughly equally to the maximum overturning, the indirect route governs its signal in denser layers. This indirect route has two branches: part of the convected water is exported rapidly on the Labrador side of the basin and part follows a longer route toward Greenland and is then carried with the boundary current. Export timescales of these two branches typically differ by 2.5 years. This study thus shows that boundary-interior exchanges are important for the pathways and the properties of water masses arriving at 53°N. It reveals a complex three-dimensional view of the convected water export, with implications for the arrival time of signals of variability therein at 53°N and thus for our understanding of the AMOC., Physical and Space Geodesy, Environmental Fluid Mechanics

Published

2021

2. Direct and Indirect Pathways of Convected Water Masses and Their impacts on the Overturning Dynamics of the Labrador Sea

Author

Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), van der Boog, C.G. (author), Spence, P. (author), Pietrzak, J.D. (author), Katsman, C.A. (author), Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), van der Boog, C.G. (author), Spence, P. (author), Pietrzak, J.D. (author), and Katsman, C.A. (author)

Abstract

The dense waters formed by wintertime convection in the Labrador Sea play a key role in setting the properties of the deep Atlantic Ocean. To understand how variability in their production might affect the Atlantic Meridional Overturning Circulation (AMOC) variability, it is essential to determine pathways and associated timescales of their export. In this study, we analyze the trajectories of Argo floats and of Lagrangian particles launched at 53°N in the boundary current and traced backward in time in a high-resolution model, to identify and quantify the importance of upstream pathways. We find that 85% of the transport carried by the particles at 53°N originates from Cape Farewell, and it is split between a direct route that follows the boundary current and an indirect route involving boundary-interior exchanges. Although both routes contribute roughly equally to the maximum overturning, the indirect route governs its signal in denser layers. This indirect route has two branches: part of the convected water is exported rapidly on the Labrador side of the basin and part follows a longer route toward Greenland and is then carried with the boundary current. Export timescales of these two branches typically differ by 2.5 years. This study thus shows that boundary-interior exchanges are important for the pathways and the properties of water masses arriving at 53°N. It reveals a complex three-dimensional view of the convected water export, with implications for the arrival time of signals of variability therein at 53°N and thus for our understanding of the AMOC., Physical and Space Geodesy, Environmental Fluid Mechanics

Published

2021

3. Pathways of the water masses exiting the Labrador Sea: The importance of boundary–interior exchanges

Author

Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), Pietrzak, J.D. (author), Katsman, C.A. (author), Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), Pietrzak, J.D. (author), and Katsman, C.A. (author)

Abstract

The water masses exiting the Labrador Sea, and in particular the dense water mass formed by convection (i.e. Labrador Sea Water, LSW), are important components of the Atlantic Meridional Overturning Circulation (AMOC). Several studies have questioned the connection of the LSW production to the AMOC variability. This is partly due to the limited understanding of how this locally formed water mass leaves the interior of the Labrador Sea. In this study, the pathways and the timescales of the water masses exiting the Labrador Sea via the boundary current are investigated by Lagrangian particle tracking. This method is applied to the output of a strongly-eddying idealized model that is capable of representing the essential physical processes involved in the cycle of convection and restratification in the Labrador Sea. The Lagrangian trajectories reveal that prior to exiting the domain the water masses follow either a fast route within the boundary current or a slower route that involves boundary current-interior exchanges. The densest water masses exiting the Labrador Sea stem from this slow route, where particles experience strong water mass transformation while in the interior. In contrast, the particles that follow the fast route experience water mass transformation in the boundary current at the western side of the domain only, yielding a lighter product. Although both routes carry roughly the same transport, we show that 60% of the overturning in density space is associated with the volume transport carried by particles that follow the slow route. This study further highlights that the export of dense water masses, which is governed by the eddy activity in the basin, yields export timescales that are usually longer than a year. This underlines the necessity of resolving the mesoscale features required to capture the interior–boundary current exchange in order to correctly represent the export of the LSW., Environmental Fluid Mechanics

Published

2020

4. Pathways of the water masses exiting the Labrador Sea: The importance of boundary–interior exchanges

Author

Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), Pietrzak, J.D. (author), Katsman, C.A. (author), Georgiou, S. (author), Ypma, S.L. (author), Brüggemann, N. (author), Sayol España, J.M. (author), Pietrzak, J.D. (author), and Katsman, C.A. (author)

Abstract

The water masses exiting the Labrador Sea, and in particular the dense water mass formed by convection (i.e. Labrador Sea Water, LSW), are important components of the Atlantic Meridional Overturning Circulation (AMOC). Several studies have questioned the connection of the LSW production to the AMOC variability. This is partly due to the limited understanding of how this locally formed water mass leaves the interior of the Labrador Sea. In this study, the pathways and the timescales of the water masses exiting the Labrador Sea via the boundary current are investigated by Lagrangian particle tracking. This method is applied to the output of a strongly-eddying idealized model that is capable of representing the essential physical processes involved in the cycle of convection and restratification in the Labrador Sea. The Lagrangian trajectories reveal that prior to exiting the domain the water masses follow either a fast route within the boundary current or a slower route that involves boundary current-interior exchanges. The densest water masses exiting the Labrador Sea stem from this slow route, where particles experience strong water mass transformation while in the interior. In contrast, the particles that follow the fast route experience water mass transformation in the boundary current at the western side of the domain only, yielding a lighter product. Although both routes carry roughly the same transport, we show that 60% of the overturning in density space is associated with the volume transport carried by particles that follow the slow route. This study further highlights that the export of dense water masses, which is governed by the eddy activity in the basin, yields export timescales that are usually longer than a year. This underlines the necessity of resolving the mesoscale features required to capture the interior–boundary current exchange in order to correctly represent the export of the LSW., Environmental Fluid Mechanics

Published

2020

5. Seasonal and regional variations of sinking in the subpolar North Atlantic from a high-resolution ocean model

Author

Sayol España, J.M. (author), Dijkstra, Henk A. (author), Katsman, C.A. (author), Sayol España, J.M. (author), Dijkstra, Henk A. (author), and Katsman, C.A. (author)

Abstract

Previous studies have indicated that most of the net sinking associated with the downward branch of the Atlantic Meridional Overturning Circulation (AMOC) must occur near the subpolar North Atlantic boundaries. In this work we have used monthly mean fields of a high-resolution ocean model (0.1 at the Equator) to quantify this sinking. To this end we have calculated the Eulerian net vertical transport (WΣ) from the modeled vertical velocities, its seasonal variability, and its spatial distribution under repeated climatological atmospheric forcing conditions. Based on this simulation, we find that for the whole subpolar North Atlantic WΣ peaks at about -14 Sv at a depth of 1139 m, matching both the mean depth and the magnitude of the meridional transport of the AMOC at 45° N. It displays a seasonal variability of around 10 Sv. Three sinking regimes are identified according to the characteristics of the accumulated WΣ with respect to the distance to the shelf: one within the first 90 km and onto the bathymetric slope at around the peak of the boundary current speed (regime I), the second between 90 and 250 km covering the remainder of the shelf where mesoscale eddies exchange properties (momentum, heat, mass) between the interior and the boundary (regime II), and the third at larger distances from the shelf where is mostly driven by the ocean's interior eddies (regime III). Regimes I and II accumulate 90% of the of the total sinking and display smaller seasonal changes and spatial variability than regime III. We find that such a distinction in regimes is also useful to describe the characteristics of WΣ in marginal seas located far from the overflow areas, although the regime boundaries can shift a few tens of kilometers inshore or offshore depending on the bathymetric slope and shelf width of each marginal sea. The largest contributions to the sinking come from the Labrador Sea, the Newfoundland region, and the overflow regions. The magnitude, seasonal variability, Environmental Fluid Mechanics

Published

2019

6. Statistical Characterization of the Observed Cold Wake Induced by North Atlantic Hurricanes

Author

Haakman, Koen (author), Sayol España, J.M. (author), van der Boog, C.G. (author), Katsman, C.A. (author), Haakman, Koen (author), Sayol España, J.M. (author), van der Boog, C.G. (author), and Katsman, C.A. (author)

Abstract

This work quantifies the magnitude, spatial structure, and temporal evolution of the cold wake left by North Atlantic hurricanes. To this end we composited the sea surface temperature anomalies (SSTA) induced by hurricane observations from 2002 to 2018 derived from the international best track archive for climate stewardship (IBTrACS). Cold wake characteristics were distinguished by a set of hurricane and oceanic properties: Hurricane translation speed and intensity, and the characteristics of the upper ocean stratification represented by two barrier layer metrics: Barrier layer thickness (BLT) and barrier layer potential energy (BLPE). The contribution of the above properties to the amplitude of the cold wake was analyzed individually and in combination. The mean magnitude of the hurricane-induced cooling was of 1.7 °C when all hurricanes without any distinction were considered, and the largest cooling was found for slow-moving, strong hurricanes passing over thinner barrier layers, with a cooling above 3.5 °C with respect to pre-storm sea surface temperature (SST) conditions. On average the cold wake needed about 60 days to disappear and experienced a strong decay in the first 20 days, when the magnitude of the cold wake had decreased by 80%. Differences between the cold wakes yielded by mostly infrared and merged infrared and microwave remote sensed SST data were also evaluated, with an overall relative underestimation of the hurricane-induced cooling of about 0.4 °C for infrared-mostly data., Environmental Fluid Mechanics

Published

2019

7. Coastal Impacts Driven by Sea-Level Rise in Cartagena de Indias

Author

Orejarena-Rondon, Andres F. (author), Sayol España, J.M. (author), Marcos, Marta (author), Otero, Luis (author), Restrepo, Juan C. (author), Hernandez-Carrasco, Ismael (author), Orfila, Alejandro (author), Orejarena-Rondon, Andres F. (author), Sayol España, J.M. (author), Marcos, Marta (author), Otero, Luis (author), Restrepo, Juan C. (author), Hernandez-Carrasco, Ismael (author), and Orfila, Alejandro (author)

Abstract

This work analyzes the coastal impacts of the combined effect of extreme waves and sea level extremes, including surges and projected mean sea level rise in Bocagrande, Cartagena (Colombia). Extreme waves are assessed from a wave reanalysis that are propagated from deep waters to the beach considering the hydrodynamic processes and taking into account the interaction between waves and the coastal elevation within the study area. First, we consider present sea level, storm surges and waves affecting the area. Next, we analyze the effect of sea level rise according to a moderate (RCP4.5) climate change scenario for the 21st century (years 2025, 2050, 2075, and 2100). The most pessimistic scenario (year 2100) yields a percentage of flooded area of 97.2%, thus revealing the major threat that represents sea level rise for coastal areas in the Caribbean Sea., Environmental Fluid Mechanics

Published

2019

8. Statistical Characterization of the Observed Cold Wake Induced by North Atlantic Hurricanes

Author

Haakman, Koen (author), Sayol España, J.M. (author), van der Boog, C.G. (author), Katsman, C.A. (author), Haakman, Koen (author), Sayol España, J.M. (author), van der Boog, C.G. (author), and Katsman, C.A. (author)

Abstract

This work quantifies the magnitude, spatial structure, and temporal evolution of the cold wake left by North Atlantic hurricanes. To this end we composited the sea surface temperature anomalies (SSTA) induced by hurricane observations from 2002 to 2018 derived from the international best track archive for climate stewardship (IBTrACS). Cold wake characteristics were distinguished by a set of hurricane and oceanic properties: Hurricane translation speed and intensity, and the characteristics of the upper ocean stratification represented by two barrier layer metrics: Barrier layer thickness (BLT) and barrier layer potential energy (BLPE). The contribution of the above properties to the amplitude of the cold wake was analyzed individually and in combination. The mean magnitude of the hurricane-induced cooling was of 1.7 °C when all hurricanes without any distinction were considered, and the largest cooling was found for slow-moving, strong hurricanes passing over thinner barrier layers, with a cooling above 3.5 °C with respect to pre-storm sea surface temperature (SST) conditions. On average the cold wake needed about 60 days to disappear and experienced a strong decay in the first 20 days, when the magnitude of the cold wake had decreased by 80%. Differences between the cold wakes yielded by mostly infrared and merged infrared and microwave remote sensed SST data were also evaluated, with an overall relative underestimation of the hurricane-induced cooling of about 0.4 °C for infrared-mostly data., Environmental Fluid Mechanics

Published

2019

9. Coastal Impacts Driven by Sea-Level Rise in Cartagena de Indias

Author

Orejarena-Rondon, Andres F. (author), Sayol España, J.M. (author), Marcos, Marta (author), Otero, Luis (author), Restrepo, Juan C. (author), Hernandez-Carrasco, Ismael (author), Orfila, Alejandro (author), Orejarena-Rondon, Andres F. (author), Sayol España, J.M. (author), Marcos, Marta (author), Otero, Luis (author), Restrepo, Juan C. (author), Hernandez-Carrasco, Ismael (author), and Orfila, Alejandro (author)

Abstract

This work analyzes the coastal impacts of the combined effect of extreme waves and sea level extremes, including surges and projected mean sea level rise in Bocagrande, Cartagena (Colombia). Extreme waves are assessed from a wave reanalysis that are propagated from deep waters to the beach considering the hydrodynamic processes and taking into account the interaction between waves and the coastal elevation within the study area. First, we consider present sea level, storm surges and waves affecting the area. Next, we analyze the effect of sea level rise according to a moderate (RCP4.5) climate change scenario for the 21st century (years 2025, 2050, 2075, and 2100). The most pessimistic scenario (year 2100) yields a percentage of flooded area of 97.2%, thus revealing the major threat that represents sea level rise for coastal areas in the Caribbean Sea., Environmental Fluid Mechanics

Published

2019

10. A modelling-based assessment of the imprint of storms on wind waves in the western Mediterranean Sea

Author

Toomey, Tim (author), Sayol España, J.M. (author), Marcos, Marta (author), Jorda, Gabriel (author), Campins, Joan (author), Toomey, Tim (author), Sayol España, J.M. (author), Marcos, Marta (author), Jorda, Gabriel (author), and Campins, Joan (author)

Abstract

This study analyses the distribution of ocean wind waves in response to extratropi- cal cyclones over the western Mediterranean Sea. To this end we use an ERA40-based database of atmospheric cyclones and a 3-hourly wind wave hind- cast with high horizontal resolution (1/6  ) based on an ERA40 downscaled forcing for the region of study. The imprint of winds on surface waves is evaluated through composites of modelled significant wave height, surface wind and wave peak period collocated under the storms. Results highlight an asymmetric pattern that depends on the translational speed and size of the cyclonic perturbations. Uncer- tainties of the composites are at most 10% at 95% confidence interval, with an aver- age maximum perturbation of significant wave height near 2 m for those cyclones moving faster than 10 m/s, Environmental Fluid Mechanics

Published

2018

11. Assessing Flood Risk Under Sea Level Rise and Extreme Sea Levels Scenarios: Application to the Ebro Delta (Spain)

Author

Sayol España, J.M. (author), Marcos, M. (author), Sayol España, J.M. (author), and Marcos, M. (author)

Abstract

This study presents a novel methodology to estimate the impact of local sea level rise and extreme surges and waves in coastal areas under climate change scenarios. The methodology is applied to the Ebro Delta, a valuable and vulnerable low-lying wetland located in the northwestern Mediterranean Sea. Projections of local sea level accounting for all contributions to mean sea level changes, including thermal expansion, dynamic changes, fresh water addition and glacial isostatic adjustment, have been obtained from regionalized sea level projections during the 21st century. Particular attention has been paid to the uncertainties, which have been derived from the spread of the multi-model ensemble combined with seasonal/inter-annual sea level variability from local tide gauge observations. Besides vertical land movements have also been integrated to estimate local relative sea level rise. On the other hand, regional projections over the Mediterranean basin of storm surges and wind-waves have been used to evaluate changes in extreme events. The compound effects of surges and extreme waves have been quantified using their joint probability distributions. Finally, offshore sea level projections from extreme events superimposed to mean sea level have been propagated onto a high resolution digital elevation model of the study region in order to construct flood hazards maps for mid and end of the 21st century and under two different climate change scenarios. The effect of each contribution has been evaluated in terms of percentage of the area exposed to coastal hazards, which will help to design more efficient protection and adaptation measures., Environmental Fluid Mechanics

Published

2018

12. Assessing Flood Risk Under Sea Level Rise and Extreme Sea Levels Scenarios: Application to the Ebro Delta (Spain)

Author

Sayol España, J.M. (author), Marcos, M. (author), Sayol España, J.M. (author), and Marcos, M. (author)

Abstract

This study presents a novel methodology to estimate the impact of local sea level rise and extreme surges and waves in coastal areas under climate change scenarios. The methodology is applied to the Ebro Delta, a valuable and vulnerable low-lying wetland located in the northwestern Mediterranean Sea. Projections of local sea level accounting for all contributions to mean sea level changes, including thermal expansion, dynamic changes, fresh water addition and glacial isostatic adjustment, have been obtained from regionalized sea level projections during the 21st century. Particular attention has been paid to the uncertainties, which have been derived from the spread of the multi-model ensemble combined with seasonal/inter-annual sea level variability from local tide gauge observations. Besides vertical land movements have also been integrated to estimate local relative sea level rise. On the other hand, regional projections over the Mediterranean basin of storm surges and wind-waves have been used to evaluate changes in extreme events. The compound effects of surges and extreme waves have been quantified using their joint probability distributions. Finally, offshore sea level projections from extreme events superimposed to mean sea level have been propagated onto a high resolution digital elevation model of the study region in order to construct flood hazards maps for mid and end of the 21st century and under two different climate change scenarios. The effect of each contribution has been evaluated in terms of percentage of the area exposed to coastal hazards, which will help to design more efficient protection and adaptation measures., Environmental Fluid Mechanics

Published

2018

13. A modelling-based assessment of the imprint of storms on wind waves in the western Mediterranean Sea

Author

Toomey, Tim (author), Sayol España, J.M. (author), Marcos, Marta (author), Jorda, Gabriel (author), Campins, Joan (author), Toomey, Tim (author), Sayol España, J.M. (author), Marcos, Marta (author), Jorda, Gabriel (author), and Campins, Joan (author)

Abstract

This study analyses the distribution of ocean wind waves in response to extratropi- cal cyclones over the western Mediterranean Sea. To this end we use an ERA40-based database of atmospheric cyclones and a 3-hourly wind wave hind- cast with high horizontal resolution (1/6  ) based on an ERA40 downscaled forcing for the region of study. The imprint of winds on surface waves is evaluated through composites of modelled significant wave height, surface wind and wave peak period collocated under the storms. Results highlight an asymmetric pattern that depends on the translational speed and size of the cyclonic perturbations. Uncer- tainties of the composites are at most 10% at 95% confidence interval, with an aver- age maximum perturbation of significant wave height near 2 m for those cyclones moving faster than 10 m/s, Environmental Fluid Mechanics

Published

2018