Your search keyword '"Wilson, Earle"' showing total 15 results

1. Mechanisms for Abrupt Summertime Circumpolar Surface Warming in the Southern Ocean.

Author

WILSON, EARLE A., BONAN, DAVID B., THOMPSON, ANDREW F., ARMSTRONG, NATALIE, and RISER, STEPHEN C.

Subjects

*ANTARCTIC oscillation, *SUMMER, *WESTERLIES, *MIXING height (Atmospheric chemistry), *OCEAN, *SEA ice

Abstract

In recent years, the Southern Ocean has experienced unprecedented surface warming and sea ice loss-a stark reversal of the sea ice expansion and surface cooling that prevailed over the preceding decades. Here, we examine the mechanisms that led to the abrupt circumpolar surface warming events that occurred in late 2016 and 2019 and assess the role of internal climate variability. A mixed layer heat budget analysis reveals that these recent circumpolar surface warming events were triggered by a weakening of the circumpolar westerlies, which decreased northward Ekman transport and accelerated the seasonal shoaling of the mixed layer. We emphasize the underappreciated effect of the latter mechanism, which played a dominant role and amplified the warming effect of air-sea heat fluxes during months of peak solar insolation. An examination of the CESM1 large ensemble demonstrates that these recent circumpolar warming events are consistent with the internal variability associated with the Southern Annular Mode (SAM), whereby negative SAM in austral spring favors shallower mixed layers and anomalously high summertime SST. A key insight from this analysis is that the seasonal phasing of springtime mixed layer depth shoaling is an important contributor to summertime SST variability in the Southern Ocean. Thus, future Southern Ocean summertime SST extremes will depend on the coevolution of mixed layer depth and surface wind variability. [ABSTRACT FROM AUTHOR]

Published

2023

2. Layered seawater intrusion and melt under grounded ice.

Author

Robel, Alexander A., Wilson, Earle, and Seroussi, Helene

Subjects

*SALTWATER encroachment, *SUBGLACIAL lakes, *ICE shelves, *ICE sheet thawing, *ICE sheets, *ICE, *PREDICTION theory, *HYDROLOGY

Abstract

Increasing melt of ice sheets at their floating or vertical interfaces with the ocean is a major driver of marine ice sheet retreat and sea level rise. However, the extent to which warm, salty seawater may drive melting under the grounded portions of ice sheets is still not well understood. Previous work has explored the possibility that dense seawater intrudes beneath relatively light subglacial freshwater discharge, similar to the "salt wedge" observed in many estuarine systems. In this study, we develop a generalized theory of layered seawater intrusion under grounded ice, including where subglacial hydrology occurs as a macroporous water sheet over impermeable beds or as microporous Darcy flow through permeable till. Using predictions from this theory, we show that seawater intrusion over flat or reverse-sloping impermeable beds may feasibly occur up to tens of kilometers upstream of a glacier terminus or grounding line. On the other hand, seawater is unlikely to intrude more than tens of meters through permeable till. Simulations using the Ice-sheet and Sea-level System Model (ISSM) show that even just a few hundred meters of basal melt caused by seawater intrusion upstream of marine ice sheet grounding lines can cause projections of marine ice sheet volume loss to be 10 %–50 % higher. Kilometers of intrusion-induced basal melt can cause projected ice sheet volume loss to more than double. These results suggest that further observational, experimental and numerical investigations are needed to determine the conditions under which seawater intrusion occurs and whether it will indeed drive rapid marine ice sheet retreat and sea level rise in the future. [ABSTRACT FROM AUTHOR]

Published

2022

3. Bathymetric Control of Subpolar Gyres and the Overturning Circulation in the Southern Ocean.

Author

Wilson, Earle A., Thompson, Andrew F., Stewart, Andrew L., and Sun, Shantong

Subjects

*OCEAN circulation, *ANTARCTIC Circumpolar Current, *OCEAN gyres, *BUOYANCY, *STRATIFIED flow

Abstract

The subpolar gyres of the Southern Ocean form an important dynamical link between the Antarctic Circumpolar Current (ACC) and the coastline of Antarctica. Despite their key involvement in the production and export of bottom water and the poleward transport of oceanic heat, these gyres are rarely acknowledged in conceptual models of the Southern Ocean circulation, which tend to focus on the zonally averaged overturning across the ACC. To isolate the effect of these gyres on the regional circulation, we carried out a set of numerical simulations with idealized representations of the Weddell Sea sector in the Southern Ocean. A key result is that the zonally oriented submarine ridge along the northern periphery of the subpolar gyre plays a fundamental role in setting the stratification and circulation across the entire region. In addition to sharpening and strengthening the horizontal circulation of the gyre, the zonal ridge establishes a strong meridional density front that separates the weakly stratified subpolar gyre from the more stratified circumpolar flow. Critically, the formation of this front shifts the latitudinal outcrop position of certain deep isopycnals such that they experience different buoyancy forcing at the surface. Additionally, the zonal ridge modifies the mechanisms by which heat is transported poleward by the ocean, favoring heat transport by transient eddies while suppressing that by stationary eddies. This study highlights the need to characterize how bathymetry at the subpolar gyre–ACC boundary may constrain the transient response of the regional circulation to changes in surface forcing. Significance Statement: This study explores the impact of seafloor bathymetry on the dynamics of subpolar gyres in the Southern Ocean. The subpolar gyres are major circulation features that connect the Antarctic Circumpolar Current (ACC) and the coastline of Antarctica. This work provides deeper insight for how the submarine ridges that exist along the northern periphery of these gyres shape the vertical distribution of tracers and overturning circulation in these regions. These findings highlight an underappreciated yet fundamentally important topographical constraint on the three-dimensional cycling of heat and carbon in the Southern Ocean—processes that have far-reaching implications for the global climate. Future work should explore how the presence of these ridges affect the time-evolving response of the Southern Ocean to changes in surface conditions. [ABSTRACT FROM AUTHOR]

Published

2022

4. Winter Upper-Ocean Stability and Ice–Ocean Feedbacks in the Sea Ice–Covered Southern Ocean.

Author

Wilson, Earle A., Riser, Stephen C., Campbell, Ethan C., and Wong, Annie P. S.

Subjects

*SEA ice, *OCEAN, *THERMOCLINES (Oceanography), *MIXING height (Atmospheric chemistry), *SURFACE forces, *ICE

Abstract

In this study, under-ice ocean data from profiling floats, instrumented seals, and shipboard casts are used to assess wintertime upper-ocean stability and heat availability in the sea ice–covered Southern Ocean. This analysis reveals that the southern Weddell Sea, which features a weak upper-ocean stratification and relatively strong thermocline, is preconditioned for exceptionally high rates of winter ventilation. This preconditioning also facilitates a strong negative feedback to winter ice growth. Idealized experiments with a 1D ice–ocean model show that the entrainment of heat into the mixed layer of this region can maintain a near-constant ice thickness over much of winter. However, this quasi-equilibrium is attained when the pycnocline is thin and supports a large temperature gradient. We find that the surface stress imparted by a powerful storm may upset this balance and lead to substantial ice melt. This response can be greatly amplified when coincident with anomalous thermocline shoaling. In more strongly stratified regions, such as near the sea ice edge of the major gyres, winter ice growth is weakly limited by the entrainment of heat into the mixed layer. Thus, the thermodynamic coupling between winter sea ice growth and ocean ventilation has significant regional variability. This regionality will influence the response of the Southern Ocean ice–ocean system to future changes in ocean stratification and surface forcing. [ABSTRACT FROM AUTHOR]

Published

2019

5. An Assessment of the Seasonal Salinity Budget for the Upper Bay of Bengal.

Author

Wilson, Earle A. and Riser, Stephen C.

Subjects

*SALINITY, *MEASUREMENT of salinity, *SEAWATER salinity

Abstract

During each summer monsoon, the Bay of Bengal is inundated by a large amount of rain and river discharge. The effects of this freshening are gradually reversed over the course of the year, with near-surface salinities typically returning to their presummer monsoon levels before the start of the next rainy season. While the forcing responsible for the summertime freshening is clear, the processes that act to restore the bay's salinity are not well understood. To examine these processes, the authors construct a basin-integrated, near-surface, seasonal salinity budget using data-assimilated output from the Hybrid Coordinate Ocean Model (HYCOM). From this salinity budget, it is deduced that vertical salt fluxes are primarily responsible for counterbalancing the near-surface freshening caused by the summertime freshwater fluxes. These vertical salt fluxes are largest during the months that immediately follow the summer monsoon, when the near-surface halocline is strongest. These results must be tempered with the knowledge that HYCOM misrepresents some key features of the bay's salinity field. In particular, the model tends to overestimate salinity along the East Indian Coastal Current during its equatorward phase. Notwithstanding these biases, these results still suggest that vertical processes have a prominent role in the bay's near-surface salinity budget. [ABSTRACT FROM AUTHOR]

Published

2016

6. Coastal Polynyas Enable Transitions Between High and Low West Antarctic Ice Shelf Melt Rates.

Author

Moorman, Ruth, Thompson, Andrew F., and Wilson, Earle A.

Subjects

*ICE shelves, *ANTARCTIC ice, *POLYNYAS, *SEA ice, *ABSOLUTE sea level change, *GLACIAL melting, *ICE sheets

Abstract

Melt rates of West Antarctic ice shelves in the Amundsen Sea track large decadal variations in the volume of warm water at their outlets. This variability is generally attributed to wind‐driven variations in warm water transport toward ice shelves. Inspired by conceptual representations of the global overturning circulation, we introduce a simple model for the evolution of the thermocline, which caps the warm water layer at the ice‐shelf front. This model demonstrates that interannual variations in coastal polynya buoyancy forcing can generate large decadal‐scale thermocline depth variations, even when the supply of warm water from the shelf‐break is fixed. The modeled variability involves transitions between bistable high and low melt regimes, enabled by feedbacks between basal melt rates and ice front stratification strength. Our simple model captures observed variations in near‐coast thermocline depth and stratification strength, and poses an alternative mechanism for warm water volume changes to wind‐driven theories. Plain Language Summary: Ice loss from the West Antarctic Ice Sheet contributes significantly to current and projected rates of global sea‐level rise. The ice sheet is primarily losing mass via glaciers that flow from the Antarctic continent into the Amundsen Sea, where floating ice shelves are exposed to much warmer ocean waters than elsewhere around Antarctica. In this work we present a simplified mathematical model for the volume of warm water at Amundsen Sea ice shelf fronts that reproduces observed patterns of warm water variability. The modeled variability relies on interactions between ice shelf melt and coastal polynyas, regions where enhanced wintertime sea‐ice production can trigger mixing that diverts heat carried by warm waters away from the ice shelf and into the atmosphere. Higher melt rates inhibit polynya convection, allowing more warm water into the ice shelf cavity and reinforcing a high melt state, whilst lower melt rates facilitate polynya convection, diverting heat away from the ice shelf and reinforcing a low melt state. Interannual variations in polynya sea‐ice production trigger shifts between these reinforcing states. Our results promote the importance of coastal processes in explaining observed variations in Amundsen Sea ice shelf melt, which have previously been attributed to remote wind patterns. Key Points: Rates of ocean‐driven Amundsen Sea ice shelf melt respond to variations in warm water transport to the coast and modification at the coastA simple Amundsen Sea continental shelf overturning model, based on water mass transformation, reveals bistable high and low melt regimesFeedbacks between glacial melt and polynya convection are central to the bistability and produce variability consistent with observations [ABSTRACT FROM AUTHOR]

Published

2023

7. Modelling the Isosteric Heating Process in a Charcoal Bed of a Solar Powered Adsorption Cooling System.

Author

Wilson, Earle A. and Kolokotroni, Maria

Subjects

*CHARCOAL, *COOLING systems, *SOLAR energy, *RENEWABLE energy industry, *TEMPERATURE measurements, *THERMODYNAMICS, *MATHEMATICAL models

Abstract

This paper addresses a problem associated with Solar Powered Adsorption Cooling (SPAC) systems. The problem is the difficulty in knowing if the complete charcoal bed reaches desorption temperature during the isosteric heating process. In addressing the issue, the process is modeled and the results are compared with those from experiments. The temperature-profile modelling of the isosteric-heating-process establishes a time-related formulation that gives the temperature, at any radius, across a cylindrical shaped bed comprising of charcoal/methanol pair of adsorbent/adsorbate; and the results from modelling compare favorably with the measured temperature-profiles obtained from the experiments. [ABSTRACT FROM AUTHOR]

Published

2014

8. Theoretical and operational thermal performance of a ‘wet’ crystalline silicon PV module under Jamaican conditions

Author

Wilson, Earle

Subjects

*EFFECT of high temperature on silicon solar cells, *PHOTOVOLTAIC cells, *COOLING, *SURFACE chemistry, *TEMPERATURE effect, *PHOTOELECTRIC cells, *MATHEMATICAL models, *ENERGY consumption

Abstract

Abstract: This paper presents the results of the impact of a gravity-fed cooling technique applied to a photovoltaic module. The experiment shows that the technique increases the power output of the module by reversing the negative effects of elevated cell temperature on open circuit voltage, and this without the use of a circulating pump. The cooling technique employs the hydraulic head of water from an upstream source as the driving force that passes water over the back of the module, and this keeps the module temperature constant. The experimental results and the results of mathematical model on which it is predicated on are in very close agreement. [Copyright &y& Elsevier]

Published

2009

9. Commercial krill fishing within a foraging supergroup of fin whales in the Southern Ocean.

Author

Ryan, Conor, Santangelo, Maya, Stephenson, Brent, Branch, Trevor A., Wilson, Earle A., and Savoca, Matthew S.

Subjects

*FISHERIES, *SEA ice, *WHALES, *BYCATCHES, *GLOBAL Ocean Observing System, *WHALING, *OCEAN

Abstract

CCAMLR can use its management mandate to protect krill-dependent predators, including baleen whales, from adverse interactions with the krill fishery (Meyer et al., [11]). Within this multispecies aggregation of krill predators there were also four commercial krill vessels actively harvesting krill (Figure 1B). Prior to krill fishing, whales and phytoplankton blooms were often spatially separated perhaps due to local top-down control of phytoplankton by krill grazing (Hardy, [6]). Industrial krill harvesting in direct competition with foraging fin whales is concerning because the regional abundance of fin whales and krill remains far below the prewhaling baseline. [Extracted from the article]

Published

2023

10. Supercooled Southern Ocean Waters.

Author

Haumann, F. Alexander, Moorman, Ruth, Riser, Stephen C., Smedsrud, Lars H., Maksym, Ted, Wong, Annie P. S., Wilson, Earle A., Drucker, Robert, Talley, Lynne D., Johnson, Kenneth S., Key, Robert M., and Sarmiento, Jorge L.

Subjects

*ICE shelves, *SEAWATER, *SEA ice, *FREEZING points, *GLACIAL melting, *OCEAN bottom, *SUPERCOOLING

Abstract

In cold polar waters, temperatures sometimes drop below the freezing point, a process referred to as supercooling. However, observational challenges in polar regions limit our understanding of the spatial and temporal extent of this phenomenon. We here provide observational evidence that supercooled waters are much more widespread in the seasonally ice‐covered Southern Ocean than previously reported. In 5.8% of all analyzed hydrographic profiles south of 55°S, we find temperatures below the surface freezing point ("potential" supercooling), and half of these have temperatures below the local freezing point ("in situ" supercooling). Their occurrence doubles when neglecting measurement uncertainties. We attribute deep coastal‐ocean supercooling to melting of Antarctic ice shelves and surface‐induced supercooling in the seasonal sea‐ice region to wintertime sea‐ice formation. The latter supercooling type can extend down to the permanent pycnocline due to convective sinking plumes—an important mechanism for vertical tracer transport and water‐mass structure in the polar ocean. Plain Language Summary: Ocean water, which contains about 34 grams of salt per kilogram of seawater, generally freezes around −1.85°C. However, seawater can be cooled to even lower temperatures without turning into ice. This phenomenon is called supercooling. Supercooled water is found in the polar oceans, typically in regions where the ocean is in contact with ice, as is the case for the enormous seasonal sea‐ice region around Antarctica. But collecting measurements in this region under the thick ice cover during the dark and cold Antarctic winter is challenging. Here, we supplement rather sparse traditional ship‐based observations with data collected by autonomous floats and instrumented marine mammals to detect and analyze where, when, and how supercooled seawater forms in the Southern Ocean. We find widespread supercooling related to melting floating glaciers (ice shelves) along the Antarctic coast and sea‐ice formation. Our analysis enables us to detect sinking supercooled plumes from sea‐ice formation, which may be important for cooling the deep ocean and transporting constituents such as carbon, nutrients, or oxygen from the ocean's surface to deeper layers. Key Points: Potential and in situ supercooling occurs in large parts of the Southern Ocean seasonal sea‐ice zoneDeep coastal supercooling from below 100 m to the ocean bottom is associated with melting ice shelves and dense shelf water formationShallow supercooling is associated with sea‐ice formation and can penetrate as deep as the permanent pycnocline [ABSTRACT FROM AUTHOR]

Published

2020

11. Air-Sea-Ice Interaction Associated with the 2016 and 2017Weddell Polynyas.

Author

Moore, Kent, Campbell, Ethan, Wilson, Earle, Brayton, Casey, Riser, Steve, Mazloff, Mathew, and Talley, Lynne

Subjects

*POLYNYAS

Published

2018

12. Cool roofs: High tech low cost solution for energy efficiency and thermal comfort in low rise low income houses in high solar radiation countries.

Author

Kolokotroni, Maria, Shittu, Emmanuel, Santos, Thiago, Ramowski, Lukasz, Mollard, Adeline, Rowe, Kirkland, Wilson, Earle, Filho, João Pereira de Brito, and Novieto, Divine

Subjects

*SOLAR radiation, *RESIDENTIAL energy conservation, *LOW-income housing, *ROOFS, *HOUSING

Abstract

Highlights • Cool roofs can improve thermal comfort of low income households near the equator. • Experimental results in Jamaica confirm improvements. • Energy models were developed for Jamaica, Ghana and Recife-Brazil. • Internal ceiling surface temperatures are reduced on average by 3.2–5.5 oC. • Cooling demand reduction is similar at 190 kWh/m2/year. Abstract Cool roofs are most effective in reducing cooling loads and alleviating overheating in locations with high solar radiation and external air temperature. This paper presents results of an experimental study of a low income house in Jamaica and a computational study in three countries around the equator: Jamaica, Northeast Brazil (Recife) and Ghana. A case-study typical of single storey houses in Jamaica was monitored before and after the installation of a cool paint on the roof; on days with average solar radiation intensity of ∼420 W/m2 and ambient air temperature of ∼28 °C, internal ceiling surface temperature is reduced by an average of 6.8 °C and internal air temperature by 2.3 °C. Monitoring results were used to calibrate successfully an EnergyPlus model; similar models were developed for Ghana and Brazil differing in size and/or construction to reflect country specific practices. Annual simulations indicate that internal ceiling surface temperatures are reduced on average by 3.2–5.5 oC and internal air temperatures by 0.75–1.2 °C. Cooling demand simulations (setpoint 24 °C) indicate similar annual potential savings in the three locations (∼190 kWh/m2/year) although estimated CO 2 emissions reduction differ reflecting electricity generation fuels. Aging of the cool roof has an impact reducing load savings by 22–26 kWh/m2/year. [ABSTRACT FROM AUTHOR]

Published

2018

13. The potential to generate solar hydrogen for cooking applications: Case studies of Ghana, Jamaica and Indonesia.

Author

Topriska, Evangelia, Kolokotroni, Maria, Dehouche, Zahir, Novieto, Divine T., and Wilson, Earle A.

Subjects

*HYDROGEN production, *SOLAR cells, *SOLUTION (Chemistry), *COOKING, *NUMERICAL analysis

Abstract

This paper evaluates one option to replace traditional cooking fuels in developing economies with a flexible, modular and clean solution of solar hydrogen, based on a numerical and experimentally tested system to address technical and safety issues. The study focuses on Ghana, Jamaica and Indonesia as examples of developing economies using fossil fuels for domestic cooking. Statistical analyses are performed and the domestic cooking demand profiles are created for these countries based on available data and a specific quantitative study in Ghana. The derived cooking demand profiles are used to size solar hydrogen plant case-studies for rural communities based on a TRNSYS numerical model. The results indicate that hydrogen plant sizing and management satisfy annual cooking demands of the communities which are 621.6 kg H 2 for Jamaica, 631 kg H 2 for Indonesia and 785 kg H 2 for Ghana. The effect of the weather data on the simulation is estimated by comparison between TMY and recent weather data for Jamaica. Finkelstein-Schafer statistics indicate differences between the composite and recent weather data, but these prove to have minor effect on simulation results, with 0.9% difference in hydrogen generation. The potential to establish solar hydrogen plants in the countries is further evaluated by creating novel solar hydrogen potential maps. [ABSTRACT FROM AUTHOR]

Published

2016

14. Solar hydrogen system for cooking applications: Experimental and numerical study.

Author

Topriska, Evangelia, Kolokotroni, Maria, Dehouche, Zahir, and Wilson, Earle

Subjects

*PHOTOVOLTAIC power systems, *SOLAR energy, *HYDROGEN, *COOKING equipment, *PROTON exchange membrane fuel cells, *COMPUTER simulation, *ELECTROLYSIS

Abstract

This paper describes the development of a semi-empirical numerical model for a solar hydrogen system consisting of a proton exchange membrane electrolyser (PEM) powered by photovoltaic panels to produce hydrogen as fuel for cooking applications, focussing on Jamaica as a suitable case-study. The model was developed in TRNSYS and includes a novel numerical component based on FORTRAN to model the operation of the PEM electrolyser. The numerical component was developed based on operational data from a purpose constructed small-scale experimental rig. The numerical model was calibrated using data from the experimental rig powered by operational data from a photovoltaic panel system in the UK and predicted photovoltaic panel power data from Jamaica. For the test conditions, experiments indicated an electrolysis maximum efficiency of 63.6%. The calibrated model was used to develop a case study analysis for a small community in Jamaica with a daily cooking demand of 39.6 kWh or 1.7 kg of H 2 gas. Simulations indicate that the H 2 production plan is sufficient for the cooking needs of the case-study. [ABSTRACT FROM AUTHOR]

Published

2015

15. One Helluva Mousetrap.

Author

Warner, Tom, Black, Jim, Pindral, Debbie, Donofrio, Jim, Zenobia III, Frank, Wilson, Earle, and Alder, Eric

Subjects

*FISHING, *EDITORS, *AQUATIC sports, *PERIODICALS, *SERIAL publications

Abstract

This article presents comments of editors of the May 2004 issue of the periodical "Field & Stream." One of the editors says that in the article "Freedom to Overfish" of the issue, the author asserts that conservation-minded saltwater anglers and groups like the Recreational Fishing Alliance are aiding overfishing and habitat destruction, when nothing could be further from the truth. The Freedom to Fish Act is being promoted to protect recreational fishermen from unwarranted and scientifically unjustified no-take reserves.

Published

2004