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1. The Coastal Ocean Environment Summer School in Ghana: Exploring the Research Capacity Building Potential of a Higher Education Informal Science Learning Program

Author

Moskel, Jennifer M., Shroyer, Emily L., Rowe, Shawn, Needham, Mark D., and Arbic, Brian K.

Abstract

The development of informal science learning programs (ISLPs) is a growing strategy among scientists seeking to engage communities. However, little scholarship exists on higher education ISLPs, limiting best practices for program development. This article explores the perceived impacts for student learners and scientist instructors of an international ISLP focused on marine science, using a mixed-methods approach of questionnaires, interviews, a task-based focus group, and participant observation. Learners perceived an increase in research skills and knowledge, and identified positive impacts associated with networking and forming connections. Learners did not significantly change their attitudes toward marine science or beliefs about careers in science. Instructors felt they helped advance their field and perceived positive impacts from cultural exchange, whereas only a few identified professional development impacts. This study suggests that higher education ISLPs should focus on creating space for different types of connections and increasing how scientists' participation is valued within the profession.

Published
2021

2. Ice mélange melt changes observed water column stratification at a tidewater glacier in Greenland.

Author

Abib, Nicole, Sutherland, David A., Peterson, Rachel, Catania, Ginny, Nash, Jonathan D., Shroyer, Emily L., Stearns, Leigh A., and Bartholomaus, Timothy C.

Subjects
SEA ice, CIRCULATION models, OCEAN circulation, FRESH water, SEAWATER, MELTWATER
Abstract

Glacial fjords often contain ice mélange, a frozen conglomeration of icebergs and sea ice, which has been postulated to influence both glacier dynamics and fjord circulation through coupled mechanical and thermodynamic processes. Ice mélange meltwater can alter stratification of the water column by releasing cool fresh water across a range of depths in the upper layer of the fjord. This meltwater input can subsequently modify the depth at which the subglacial discharge plume reaches neutral buoyancy and therefore the underlying buoyancy-driven fjord circulation and heat exchange with warm ocean shelf waters. Despite a spate of recent modeling studies exploring these proposed feedbacks, we lack in situ observations quantifying changes to the water column induced by ice mélange meltwater. Here we use a novel dataset collected before and after the melt, breakup, and down-fjord transport of ephemeral ice mélange in front of Kangilliup Sermia (Rink Isbræ) to directly investigate the extent to which ice mélange meltwater can modify glacier-adjacent water properties. We find that even a short-lived ice mélange event (4 d) can cause substantial cooling (0.18 °C) and freshening (0.25 g kg−1) of the water column that leads to stratification change down to the depth of the outflowing discharge plume. We compare our observations to an adjacent fjord, Kangerlussuup Sermia, where ice mélange seldom forms in the summertime and show that the presence or absence of ice mélange melt creates fundamental differences in the upper-layer hydrography of the two areas. These observations provide critical constraints for and agreement with recent modeling studies that have suggested ice mélange meltwater needs to be included in ocean circulation models for glaciers with deep grounding lines and high ice fluxes, which are precisely the glaciers exhibiting the largest-magnitude terminus retreats at present. [ABSTRACT FROM AUTHOR]

Published
2024
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3. List of contributors

Author

Abernathey, Ryan, primary, Brearley, J. Alexander, additional, Couespel, Damien, additional, de Lavergne, Casimir, additional, Fer, Ilker, additional, Fox-Kemper, Baylor, additional, Frajka-Williams, Eleanor, additional, Gille, Sarah T., additional, Gnanadesikan, Anand, additional, Groeskamp, Sjoerd, additional, Gula, Jonathan, additional, Hallberg, Robert, additional, Johnson, Helen L., additional, Johnson, Leah, additional, Kelly, Samuel, additional, Lachkar, Zouhair, additional, Lenn, Yueng-Djern, additional, Lévy, Marina, additional, MacKinnon, Jennifer A., additional, Mahadevan, Amala, additional, Marshall, David P., additional, McDougall, Trevor J., additional, Melet, Angélique V., additional, Meredith, Michael, additional, Moum, James N., additional, Musgrave, Ruth, additional, Nash, Jonathan D., additional, Natarov, Andrei, additional, Naveira Garabato, Alberto, additional, Nikurashin, Maxim, additional, Palter, Jaime B., additional, Pollmann, Friederike, additional, Polzin, Kurt L., additional, Pradal, Marie-Aude, additional, Qiao, Fangli, additional, Resplandy, Laure, additional, Richards, Kelvin J., additional, Shcherbina, Andrey, additional, Sheen, Katy L., additional, Shroyer, Emily L., additional, Smyth, William D., additional, Sundermeyer, Miles A., additional, Swart, Sebastiaan, additional, Taylor, John, additional, Thomas, Leif N., additional, Thompson, Andrew F., additional, Timmermans, Mary-Louise, additional, Whalen, Caitlin B., additional, Zhai, Xiaoming, additional, and Zika, Jan, additional

Published
2022
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4. Mixing in equatorial oceans

Author

Moum, James N., primary, Natarov, Andrei, additional, Richards, Kelvin J., additional, Shroyer, Emily L., additional, and Smyth, William D., additional

Published
2022
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8. Measuring Ocean Turbulence

Author

Shroyer, Emily L., Nash, Jonathan D., Waterhouse, Amy F., Moum, James N., Venkatesan, R., editor, Tandon, Amit, editor, D'Asaro, Eric, editor, and Atmanand, M. A., editor

Published
2018
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12. Ice mélange melt drives changes in observed water column stratification at a tidewater glacier in Greenland.

Author

Abib, Nicole, Sutherland, David A., Peterson, Rachel, Catania, Ginny, Nash, Jonathan D., Shroyer, Emily L., Stearns, Leigh A., and Bartholomaus, Timothy C.

Subjects
MELTWATER, ICE shelves, GLACIERS, SEA ice, ICE, TIDE-waters, CIRCULATION models, OCEAN circulation
Abstract

Glacial fjords often contain ice mélange, a frozen conglomeration of icebergs, brash ice, and sea ice, that have been postulated to influence both glacier dynamics and fjord circulation through coupled mechanical and thermodynamic processes. Ice mélange meltwater can alter stratification of the water column by releasing cool, fresh water across a range of depths in the upper layer of the fjord. This meltwater input can subsequently modify the depth at which the subglacial discharge plume reaches neutral buoyancy and therefore the underlying buoyancy-driven fjord circulation and heat exchange with warm ocean shelf waters. Despite a spate of recent modelling studies exploring these proposed feedbacks, we lack in situ observations quantifying changes to the water column induced by ice mélange meltwater. Here we use a novel dataset collected before and after the melt, breakup, and down-fjord transport of an ephemeral ice mélange in front of Kangilliup Sermia (Rink Isbræ) to directly investigate the extent to which ice mélange meltwater can modify glacier-adjacent water properties. We find that even a short-lived ice mélange (4 days) can cause substantial cooling (0.18 °C) and freshening (0.25 g kg-1) of the water column that leads to stratification change down to the depth of the outflowing discharge plume. We compare our observations to an adjacent fjord, Kangerlussuup Sermia, where ice mélange seldom forms in the summertime, and show that the presence or absence of ice mélange melt creates fundamental differences in their upper layer hydrography. These observations provide critical constraints for recent modelling studies that have suggested ice mélange meltwater needs to be included in ocean circulation models for glaciers with deep grounding lines and high ice fluxes, which are precisely the glaciers exhibiting the largest magnitude terminus retreats at present. [ABSTRACT FROM AUTHOR]

Published
2024
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14. A Tale of Two Spicy Seas

Author

MacKinnon, Jennifer A., Nash, Jonathan D., Alford, Matthew H., Lucas, Andrew J., Mickett, John B., Shroyer, Emily L., Waterhouse, Amy F., Tandon, Amit, Sengupta, Debasis, Mahadevan, Amala, Ravichandran, M., Pinkel, Robert, Rudnick, Daniel L., Whalen, Caitlin B., Alberty, Marion S., Lekha, J. Sree, Fine, Elizabeth C., Chaudhuri, Dipanjan, and Wagner, Gregory L.

Published
2016

23. Deep Cycle Turbulence in Atlantic and Pacific Cold Tongues

Author

Moum, James N., Hughes, Kenneth G., Shroyer, Emily L., Smyth, William D., Cherian, Deepak, Warner, Sally J., Bourlès, Bernard, Brandt, Peter, Dengler, Marcus, Moum, James N., Hughes, Kenneth G., Shroyer, Emily L., Smyth, William D., Cherian, Deepak, Warner, Sally J., Bourlès, Bernard, Brandt, Peter, and Dengler, Marcus

Published
2022
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24. Bay of Bengal intraseasonal oscillations and the 2018 monsoon onset

Author

Shroyer, Emily L., Tandon, Amit, Sengupta, Debasis, Fernando, Harindra J. S., Lucas, Andrew J., Farrar, J. Thomas, Chattopadhyay, Rajib, de Szoeke, Simon P., Flatau, Maria, Rydbeck, Adam, Wijesekera, Hemantha W., McPhaden, Michael J., Seo, Hyodae, Subramanian, Aneesh C., Venkatesan, Ramasamy, Joseph, Jossia K., Ramsundaram, S., Gordon, Arnold L., Bohman, Shannon M., Pérez, Jaynise, Simoes-Sousa, Iury T., Jayne, Steven R., Todd, Robert E., Bhat, G. S., Lankhorst, Matthias, Schlosser, Tamara L., Adams, Katherine, Jinadasa, S. U. P., Mathur, Manikandan, Mohapatra, Mrutyunjay, Rama Rao, E. Pattabhi, Sahai, Atul Kumar, Sharma, Rashmi, Lee, Craig, Rainville, Luc, Cherian, Deepak A., Cullen, Kerstin, Centurioni, Luca R., Hormann, Verena, MacKinnon, Jennifer A., Send, Uwe, Anutaliya, Arachaporn, Waterhouse, Amy F., Black, Garrett S., Dehart, Jeremy A., Woods, Kaitlyn M., Creegan, Edward, Levy, Gad, Kantha, Lakshmi, Subrahmanyam, Bulusu, Shroyer, Emily L., Tandon, Amit, Sengupta, Debasis, Fernando, Harindra J. S., Lucas, Andrew J., Farrar, J. Thomas, Chattopadhyay, Rajib, de Szoeke, Simon P., Flatau, Maria, Rydbeck, Adam, Wijesekera, Hemantha W., McPhaden, Michael J., Seo, Hyodae, Subramanian, Aneesh C., Venkatesan, Ramasamy, Joseph, Jossia K., Ramsundaram, S., Gordon, Arnold L., Bohman, Shannon M., Pérez, Jaynise, Simoes-Sousa, Iury T., Jayne, Steven R., Todd, Robert E., Bhat, G. S., Lankhorst, Matthias, Schlosser, Tamara L., Adams, Katherine, Jinadasa, S. U. P., Mathur, Manikandan, Mohapatra, Mrutyunjay, Rama Rao, E. Pattabhi, Sahai, Atul Kumar, Sharma, Rashmi, Lee, Craig, Rainville, Luc, Cherian, Deepak A., Cullen, Kerstin, Centurioni, Luca R., Hormann, Verena, MacKinnon, Jennifer A., Send, Uwe, Anutaliya, Arachaporn, Waterhouse, Amy F., Black, Garrett S., Dehart, Jeremy A., Woods, Kaitlyn M., Creegan, Edward, Levy, Gad, Kantha, Lakshmi, and Subrahmanyam, Bulusu

Abstract

Author Posting. © American Meteorological Society, 2021. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Bulletin of the American Meteorological Society 102(10), (2021): E1936–E1951, https://doi.org/10.1175/BAMS-D-20-0113.1., In the Bay of Bengal, the warm, dry boreal spring concludes with the onset of the summer monsoon and accompanying southwesterly winds, heavy rains, and variable air–sea fluxes. Here, we summarize the 2018 monsoon onset using observations collected through the multinational Monsoon Intraseasonal Oscillations in the Bay of Bengal (MISO-BoB) program between the United States, India, and Sri Lanka. MISO-BoB aims to improve understanding of monsoon intraseasonal variability, and the 2018 field effort captured the coupled air–sea response during a transition from active-to-break conditions in the central BoB. The active phase of the ∼20-day research cruise was characterized by warm sea surface temperature (SST > 30°C), cold atmospheric outflows with intermittent heavy rainfall, and increasing winds (from 2 to 15 m s−1). Accumulated rainfall exceeded 200 mm with 90% of precipitation occurring during the first week. The following break period was both dry and clear, with persistent 10–12 m s−1 wind and evaporation of 0.2 mm h−1. The evolving environmental state included a deepening ocean mixed layer (from ∼20 to 50 m), cooling SST (by ∼1°C), and warming/drying of the lower to midtroposphere. Local atmospheric development was consistent with phasing of the large-scale intraseasonal oscillation. The upper ocean stores significant heat in the BoB, enough to maintain SST above 29°C despite cooling by surface fluxes and ocean mixing. Comparison with reanalysis indicates biases in air–sea fluxes, which may be related to overly cool prescribed SST. Resolution of such biases offers a path toward improved forecasting of transition periods in the monsoon., This work was supported through the U.S. Office of Naval Research’s Departmental Research Initiative: Monsoon Intraseasonal Oscillations in the Bay of Bengal, the Indian Ministry of Earth Science’s Ocean Mixing and Monsoons Program, and the Sri Lankan National Aquatic Resources Research and Development Agency. We thank the Captain and crew of the R/V Thompson for their help in data collection. Surface atmospheric fields included fluxes were quality controlled and processed by the Boundary Layer Observations and Processes Team within the NOAA Physical Sciences Laboratory. Forecast analysis was completed by India Meteorological Department. Drone image was taken by Shreyas Kamat with annotations by Gualtiero Spiro Jaeger. We also recognize the numerous researchers who supported cruise- and land-based measurements. This work represents Lamont-Doherty Earth Observatory contribution number 8503, and PMEL contribution number 5193., 2022-04-01

Published
2022

25. Progress in understanding of Indian Ocean circulation, variability, air-sea exchange, and impacts on biogeochemistry

Author

Phillips, Helen E., Tandon, Amit, Furue, Ryo, Hood, Raleigh R., Ummenhofer, Caroline C., Benthuysen, Jessica A., Menezes, Viviane V., Hu, Shijian, Webber, Ben, Sanchez-Franks, Alejandra, Cherian, Deepak A., Shroyer, Emily L., Feng, Ming, Wijesekera, Hemantha W., Chatterjee, Abhisek, Yu, Lisan, Hermes, Juliet, Murtugudde, Raghu, Tozuka, Tomoki, Su, Danielle, Singh, Arvind, Centurioni, Luca R., Prakash, Satya, Wiggert, Jerry D., Phillips, Helen E., Tandon, Amit, Furue, Ryo, Hood, Raleigh R., Ummenhofer, Caroline C., Benthuysen, Jessica A., Menezes, Viviane V., Hu, Shijian, Webber, Ben, Sanchez-Franks, Alejandra, Cherian, Deepak A., Shroyer, Emily L., Feng, Ming, Wijesekera, Hemantha W., Chatterjee, Abhisek, Yu, Lisan, Hermes, Juliet, Murtugudde, Raghu, Tozuka, Tomoki, Su, Danielle, Singh, Arvind, Centurioni, Luca R., Prakash, Satya, and Wiggert, Jerry D.

Abstract

© The Author(s), 2021. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Phillips, H. E., Tandon, A., Furue, R., Hood, R., Ummenhofer, C. C., Benthuysen, J. A., Menezes, V., Hu, S., Webber, B., Sanchez-Franks, A., Cherian, D., Shroyer, E., Feng, M., Wijesekera, H., Chatterjee, A., Yu, L., Hermes, J., Murtugudde, R., Tozuka, T., Su, D., Singh, A., Centurioni, L., Prakash, S., Wiggert, J. Progress in understanding of Indian Ocean circulation, variability, air-sea exchange, and impacts on biogeochemistry. Ocean Science, 17(6), (2021): 1677–1751, https://doi.org/10.5194/os-17-1677-2021., Over the past decade, our understanding of the Indian Ocean has advanced through concerted efforts toward measuring the ocean circulation and air–sea exchanges, detecting changes in water masses, and linking physical processes to ecologically important variables. New circulation pathways and mechanisms have been discovered that control atmospheric and oceanic mean state and variability. This review brings together new understanding of the ocean–atmosphere system in the Indian Ocean since the last comprehensive review, describing the Indian Ocean circulation patterns, air–sea interactions, and climate variability. Coordinated international focus on the Indian Ocean has motivated the application of new technologies to deliver higher-resolution observations and models of Indian Ocean processes. As a result we are discovering the importance of small-scale processes in setting the large-scale gradients and circulation, interactions between physical and biogeochemical processes, interactions between boundary currents and the interior, and interactions between the surface and the deep ocean. A newly discovered regional climate mode in the southeast Indian Ocean, the Ningaloo Niño, has instigated more regional air–sea coupling and marine heatwave research in the global oceans. In the last decade, we have seen rapid warming of the Indian Ocean overlaid with extremes in the form of marine heatwaves. These events have motivated studies that have delivered new insight into the variability in ocean heat content and exchanges in the Indian Ocean and have highlighted the critical role of the Indian Ocean as a clearing house for anthropogenic heat. This synthesis paper reviews the advances in these areas in the last decade., Helen E. Phillips acknowledges support from the Earth Systems and Climate Change Hub and Climate Systems Hub of the Australian Government's National Environmental Science Programme and the ARC Centre of Excellence for Climate Extremes. Amit Tandon acknowledges the US Office of Naval Research. This is INCOIS contribution no. 437.

Published
2022

26. Shear turbulence in the high-wind Southern Ocean using direct measurements

Author

Ferris, Laur, Gong, Donglai, Clayson, Carol A., Merrifield, Sophia T., Shroyer, Emily L., Smith, Madison M., St. Laurent, Louis C., Ferris, Laur, Gong, Donglai, Clayson, Carol A., Merrifield, Sophia T., Shroyer, Emily L., Smith, Madison M., and St. Laurent, Louis C.

Abstract

Author Posting. © American Meteorological Society, 2022. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Journal of Physical Oceanography 52(10), (2022): 2325–2341, https://doi.org/10.1175/jpo-d-21-0015.1., The ocean surface boundary layer is a gateway of energy transfer into the ocean. Wind-driven shear and meteorologically forced convection inject turbulent kinetic energy into the surface boundary layer, mixing the upper ocean and transforming its density structure. In the absence of direct observations or the capability to resolve subgrid-scale 3D turbulence in operational ocean models, the oceanography community relies on surface boundary layer similarity scalings (BLS) of shear and convective turbulence to represent this mixing. Despite their importance, near-surface mixing processes (and ubiquitous BLS representations of these processes) have been undersampled in high-energy forcing regimes such as the Southern Ocean. With the maturing of autonomous sampling platforms, there is now an opportunity to collect high-resolution spatial and temporal measurements in the full range of forcing conditions. Here, we characterize near-surface turbulence under strong wind forcing using the first long-duration glider microstructure survey of the Southern Ocean. We leverage these data to show that the measured turbulence is significantly higher than standard shear-convective BLS in the shallower parts of the surface boundary layer and lower than standard shear-convective BLS in the deeper parts of the surface boundary layer; the latter of which is not easily explained by present wave-effect literature. Consistent with the CBLAST (Coupled Boundary Layers and Air Sea Transfer) low winds experiment, this bias has the largest magnitude and spread in the shallowest 10% of the actively mixing layer under low-wind and breaking wave conditions, when relatively low levels of turbulent kinetic energy (TKE) in surface regime are easily biased by wave events., This paper is VIMS Contribution 4103. Computational resources were provided by the VIMS Ocean-Atmosphere and Climate Change Research Fund. AUSSOM was supported by the OCE Division of the National Science Foundation (1558639).

Published
2022

27. Flippin' χ SOLO, an Upper-Ocean Autonomous Turbulence-Profiling Float.

Author

Moum, James N., Rudnick, Daniel L., Shroyer, Emily L., Hughes, Kenneth G., Reineman, Benjamin D., Grindley, Kyle, Sherman, Jeffrey T., Vutukur, Pavan, Appledorn, Craig Van, Latham, Kerry, Moulin, Aurélie J., and Johnston, T. M. Shaun

Subjects
OCEAN conditions (Weather), CENTER of mass, PRESSURE sensors, SURFACE forces, ANTENNAS (Electronics), OCEAN waves
Abstract

A new autonomous turbulence profiling float has been designed, built, and tested in field trials off Oregon. Flippin' χSOLO (FχS) employs a SOLO-II buoyancy engine that not only changes but also shifts ballast to move the center of mass to positions on either side of the center of buoyancy, thus causing FχS to flip. FχS is outfitted with a full suite of turbulence sensors—two shear probes, two fast thermistors, and pitot tube, as well as a pressure sensor and three-axis linear accelerometers. FχS descends and ascends with turbulence sensors leading, thereby permitting measurement through the sea surface. The turbulence sensors are housed antipodal from communication antennas so as to eliminate flow disturbance. By flipping at the sea surface, antennas are exposed for communications. The mission of FχS is to provide intensive profiling measurements of the upper ocean from 240 m and through the sea surface, particularly during periods of extreme surface forcing. While surfaced, accelerometers provide estimates of wave height spectra and significant wave height. From 3.5 day field trials, here we evaluate (i) the statistics from two FχS units and our established shipboard profiler, Chameleon, and (ii) FχS-based wave statistics by comparison to a nearby NOAA wave buoy. Significance Statement: The oceanographic fleet of Argo autonomous profilers yields important data that define the state of the ocean's interior. Continued deployments over time define the evolution of the ocean's interior. A significant next step will be to include turbulence measurements on these profilers, leading to estimates of thermodynamic mixing rates that predict future states of the ocean's interior. An autonomous turbulence profiler that employs the buoyancy engine, mission logic, and remote communication of one particular Argo float is described herein. The Flippin' χSOLO is an upper-ocean profiler tasked with rapid and continuous profiling of the upper ocean during weather conditions that preclude shipboard profiling and that includes the upper 10 m that is missed by shipboard turbulence profilers. [ABSTRACT FROM AUTHOR]

Published
2023
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28. Are Any Coastal Internal Tides Predictable?

Author

NASH, JONATHAN D., SHROYER, EMILY L., KELLY, SAMUEL M., INALL, MARK E., DUDA, TIMOTHY F., LEVINE, MURRAY D., JONES, NICOLE L., and MUSGRAVE, RUTH C.

Published
2012

29. Deep Cycle Turbulence in Atlantic and Pacific Cold Tongues

Author

Moum, James N., primary, Hughes, Kenneth G., additional, Shroyer, Emily L., additional, Smyth, William D., additional, Cherian, Deepak, additional, Warner, Sally J., additional, Bourlès, Bernard, additional, Brandt, Peter, additional, and Dengler, Marcus, additional

Published
2022
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31. Deep cycle turbulence in Atlantic and Pacific cold tongues

Author

Moum, Jim, primary, Hughes, Kenneth G., additional, Shroyer, Emily L, additional, Smyth, William, additional, Cherian, Deepak, additional, Warner, Sally Jane, additional, Bourlès, Bernard, additional, Brandt, Peter, additional, and Dengler, Marcus, additional

Published
2022
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33. How spice is stirred in the Bay of Bengal

Author

Spiro Jaeger, Gualtiero, MacKinnon, Jennifer A., Lucas, Andrew J., Shroyer, Emily L., Nash, Jonathan D., Tandon, Amit, Farrar, J. Thomas, Mahadevan, Amala, Spiro Jaeger, Gualtiero, MacKinnon, Jennifer A., Lucas, Andrew J., Shroyer, Emily L., Nash, Jonathan D., Tandon, Amit, Farrar, J. Thomas, and Mahadevan, Amala

Abstract

Author Posting. © American Meteorological Society, 2020. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Journal of Physical Oceanography 50(9), (2020): 2669-2688, doi:10.1175/JPO-D-19-0077.1, The scale-dependent variance of tracer properties in the ocean bears the imprint of the oceanic eddy field. Anomalies in spice (which combines anomalies in temperature T and salinity S on isopycnal surfaces) act as passive tracers beneath the surface mixed layer (ML). We present an analysis of spice distributions along isopycnals in the upper 200 m of the ocean, calculated with over 9000 vertical profiles of T and S measured along ~4800 km of ship tracks in the Bay of Bengal. The data are from three separate research cruises—in the winter monsoon season of 2013 and in the late and early summer monsoon seasons of 2015 and 2018. We present a spectral analysis of horizontal tracer variance statistics on scales ranging from the submesoscale (~1 km) to the mesoscale (~100 km). Isopycnal layers that are closer to the ML-base exhibit redder spectra of tracer variance at scales ≲10 km than is predicted by theories of quasigeostrophic turbulence or frontogenesis. Two plausible explanations are postulated. The first is that stirring by submesoscale motions and shear dispersion by near-inertial waves enhance effective horizontal mixing and deplete tracer variance at horizontal scales ≲10 km in this region. The second is that the spice anomalies are coherent with dynamical properties such as potential vorticity, and not interpretable as passively stirred., We are grateful to the captain and crew of the R/V Roger Revelle and the R/V Thomas G. Thompson, and all ASIRI-OMM and MISO-BOB scientists. We thank Prof. Andrew Thompson and an anonymous reviewer for suggestions that improved the manuscript. This work was carried out under the Office of Naval Research’s Air-Sea Interaction Regional Initiative (ASIRI) and Monsoon Intra-Seasonal Oscillations in the Bay of Bengal (MISO-BOB) research initiatives, in collaboration with the Indian Ministry of Earth Science’s Ocean Mixing and Monsoons (OMM) initiative supported by the Monsoon Mission. Support came from ONR Grants N00014-16-1-2470, N00014-13-1-0451, N00014-17-1-2390 (G.S.J. and A.M.), N00014-14-1-0455 (J.M. and J.N), N00014-17-1-2511 (J.M.), N00014-13-1-0489, N00014-17-1-2391 (A.L.), N00014-15-1-2634 (E.S.), N00014-13-1-0456, N00014-17-1-2355 (A.T.), and N00014-13-1-0453, N00014-17-1-2880 (J.F.)., 2021-02-28

Published
2021

38. On the future of Argo: A global, full-depth, multi-disciplinary array

Author

Roemmich, Dean, Alford, Matthew H., Claustre, Hervé, Johnson, Kenneth S., King, Brian, Moum, James N., Oke, Peter, Owens, W. Brechner, Pouliquen, Sylvie, Purkey, Sarah G., Scanderbeg, Megan, Suga, Koushirou, Wijffels, Susan E., Zilberman, Nathalie, Bakker, Dorothee, Baringer, Molly O., Belbeoch, Mathieu, Bittig, Henry C., Boss, Emmanuel S., Calil, Paulo H. R., Carse, Fiona, Carval, Thierry, Chai, Fei, Conchubhair, Diarmuid Ó., d’Ortenzio, Fabrizio, Dall'Olmo, Giorgio, Desbruyeres, Damien, Fennel, Katja, Fer, Ilker, Ferrari, Raffaele, Forget, Gael, Freeland, Howard, Fujiki, Tetsuichi, Gehlen, Marion, Geenan, Blair, Hallberg, Robert, Hibiya, Toshiyuki, Hosoda, Shigeki, Jayne, Steven R., Jochum, Markus, Johnson, Gregory C., Kang, KiRyong, Kolodziejczyk, Nicolas, Körtzinger, Arne, Le Traon, Pierre-Yves, Lenn, Yueng-Djern, Maze, Guillaume, Mork, Kjell Arne, Morris, Tamaryn, Nagai, Takeyoshi, Nash, Jonathan D., Naveira Garabato, Alberto C., Olsen, Are, Pattabhi Rama Rao, Eluri, Prakash, Satya, Riser, Stephen C., Schmechtig, Catherine, Schmid, Claudia, Shroyer, Emily L., Sterl, Andreas, Sutton, Philip J. H., Talley, Lynne D., Tanhua, Toste, Thierry, Virginie, Thomalla, Sandy J., Toole, John M., Troisi, Ariel, Trull, Thomas W., Turton, Jon, Velez-Belchi, Pedro, Walczowski, Waldemar, Wang, Haili, Wanninkhof, Rik, Waterhouse, Amy F., Waterman, Stephanie N., Watson, Andrew J., Wilson, Cara, Wong, Annie P. S., Xu, Jianping, Yasuda, Ichiro, Roemmich, Dean, Alford, Matthew H., Claustre, Hervé, Johnson, Kenneth S., King, Brian, Moum, James N., Oke, Peter, Owens, W. Brechner, Pouliquen, Sylvie, Purkey, Sarah G., Scanderbeg, Megan, Suga, Koushirou, Wijffels, Susan E., Zilberman, Nathalie, Bakker, Dorothee, Baringer, Molly O., Belbeoch, Mathieu, Bittig, Henry C., Boss, Emmanuel S., Calil, Paulo H. R., Carse, Fiona, Carval, Thierry, Chai, Fei, Conchubhair, Diarmuid Ó., d’Ortenzio, Fabrizio, Dall'Olmo, Giorgio, Desbruyeres, Damien, Fennel, Katja, Fer, Ilker, Ferrari, Raffaele, Forget, Gael, Freeland, Howard, Fujiki, Tetsuichi, Gehlen, Marion, Geenan, Blair, Hallberg, Robert, Hibiya, Toshiyuki, Hosoda, Shigeki, Jayne, Steven R., Jochum, Markus, Johnson, Gregory C., Kang, KiRyong, Kolodziejczyk, Nicolas, Körtzinger, Arne, Le Traon, Pierre-Yves, Lenn, Yueng-Djern, Maze, Guillaume, Mork, Kjell Arne, Morris, Tamaryn, Nagai, Takeyoshi, Nash, Jonathan D., Naveira Garabato, Alberto C., Olsen, Are, Pattabhi Rama Rao, Eluri, Prakash, Satya, Riser, Stephen C., Schmechtig, Catherine, Schmid, Claudia, Shroyer, Emily L., Sterl, Andreas, Sutton, Philip J. H., Talley, Lynne D., Tanhua, Toste, Thierry, Virginie, Thomalla, Sandy J., Toole, John M., Troisi, Ariel, Trull, Thomas W., Turton, Jon, Velez-Belchi, Pedro, Walczowski, Waldemar, Wang, Haili, Wanninkhof, Rik, Waterhouse, Amy F., Waterman, Stephanie N., Watson, Andrew J., Wilson, Cara, Wong, Annie P. S., Xu, Jianping, and Yasuda, Ichiro

Abstract

© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Roemmich, D., Alford, M. H., Claustre, H., Johnson, K., King, B., Moum, J., Oke, P., Owens, W. B., Pouliquen, S., Purkey, S., Scanderbeg, M., Suga, T., Wijffels, S., Zilberman, N., Bakker, D., Baringer, M., Belbeoch, M., Bittig, H. C., Boss, E., Calil, P., Carse, F., Carval, T., Chai, F., Conchubhair, D. O., d'Ortenzio, F., Dall'Olmo, G., Desbruyeres, D., Fennel, K., Fer, I., Ferrari, R., Forget, G., Freeland, H., Fujiki, T., Gehlen, M., Greenan, B., Hallberg, R., Hibiya, T., Hosoda, S., Jayne, S., Jochum, M., Johnson, G. C., Kang, K., Kolodziejczyk, N., Kortzinger, A., Le Traon, P., Lenn, Y., Maze, G., Mork, K. A., Morris, T., Nagai, T., Nash, J., Garabato, A. N., Olsen, A., Pattabhi, R. R., Prakash, S., Riser, S., Schmechtig, C., Schmid, C., Shroyer, E., Sterl, A., Sutton, P., Talley, L., Tanhua, T., Thierry, V., Thomalla, S., Toole, J., Troisi, A., Trull, T. W., Turton, J., Velez-Belchi, P. J., Walczowski, W., Wang, H., Wanninkhof, R., Waterhouse, A. F., Waterman, S., Watson, A., Wilson, C., Wong, A. P. S., Xu, J., & Yasuda, I. On the future of Argo: A global, full-depth, multi-disciplinary array. Frontiers in Marine Science, 6, (2019): 439, doi:10.3389/fmars.2019.00439., The Argo Program has been implemented and sustained for almost two decades, as a global array of about 4000 profiling floats. Argo provides continuous observations of ocean temperature and salinity versus pressure, from the sea surface to 2000 dbar. The successful installation of the Argo array and its innovative data management system arose opportunistically from the combination of great scientific need and technological innovation. Through the data system, Argo provides fundamental physical observations with broad societally-valuable applications, built on the cost-efficient and robust technologies of autonomous profiling floats. Following recent advances in platform and sensor technologies, even greater opportunity exists now than 20 years ago to (i) improve Argo’s global coverage and value beyond the original design, (ii) extend Argo to span the full ocean depth, (iii) add biogeochemical sensors for improved understanding of oceanic cycles of carbon, nutrients, and ecosystems, and (iv) consider experimental sensors that might be included in the future, for example to document the spatial and temporal patterns of ocean mixing. For Core Argo and each of these enhancements, the past, present, and future progression along a path from experimental deployments to regional pilot arrays to global implementation is described. The objective is to create a fully global, top-to-bottom, dynamically complete, and multidisciplinary Argo Program that will integrate seamlessly with satellite and with other in situ elements of the Global Ocean Observing System (Legler et al., 2015). The integrated system will deliver operational reanalysis and forecasting capability, and assessment of the state and variability of the climate system with respect to physical, biogeochemical, and ecosystems parameters. It will enable basic research of unprecedented breadth and magnitude, and a wealth of ocean-education and outreach opportunities., DR, MS, and NZ were supported by the US Argo Program through the NOAA Grant NA15OAR4320071 (CIMEC). WO, SJ, and SWi were supported by the US Argo Program through the NOAA Grant NA14OAR4320158 (CINAR). EuroArgo scientists were supported by the two grants: (1) AtlantOS funding by the European Union’s Horizon 2020 Research and Innovation Programme under the Grant Agreement No. 633211 and (2) Monitoring the Oceans and Climate Change with Argo (MOCCA) Co-funded by the European Maritime and Fisheries Fund (EMFF) Project No. SI2.709624. This manuscript represents a contribution to the following research projects for HC, CaS, and FD: remOcean (funded by the European Research Council, grant 246777), NAOS (funded by the Agence Nationale de la Recherche in the frame of the French “Equipement d’avenir” program, grant ANR J11R107-F), AtlantOS (funded by the European Union’s Horizon 2020 Research and Innovation Programme, grant 2014-633211), and the BGC-Argo project funded by the CNES. DB was funded by the EU RINGO project (730944 H2020-INFRADEV-2016-1). RF was supported by the AGS-1835576. GCJ was supported by the Global Ocean Monitoring and Observing Program, National Oceanic and Atmospheric Administration (NOAA), U.S., and the Department of Commerce and NOAA Research. LT was funded under the SOCCOM Grant No. NSF PLR-1425989. VT’s contribution was supported by the French National Research Agency (ANR) through the EQUIPEX NAOS (Novel Argo Observing System) under the reference ANR-10-EQPX-40 and by the European H2020 Research and Innovation Programme through the AtlantOS project under the reference 633211. WW was supported by the Argo Poland program through the Ministry of Sciences and Higher Education Grant No. DIR/WK/2016/12. AmW was funded by the NSF-OCE1434722. K-RK is funded by the National Institute of Meteorological Sciences’ Research and Development Program “Development of Marine Meteorology Monitoring and Next-generation Ocean Forecasting System” under the grant KMA2018

Published
2019

39. Observations and modeling of a hydrothermal plume in Yellowstone Lake

Author

Sohn, Robert A., Luttrell, Karen M., Shroyer, Emily L., Stranne, Christian, Harris, Robert N., Favorito, Julia E., Sohn, Robert A., Luttrell, Karen M., Shroyer, Emily L., Stranne, Christian, Harris, Robert N., and Favorito, Julia E.

Abstract

Author Posting. © American Geophysical Union, 20XX. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Geophysical Research Letters 46(12), (2019): 6435-6442, doi:10.1029/2019GL082523., Acoustic Doppler current profiler and conductivity‐temperature‐depth data acquired in Yellowstone Lake reveal the presence of a buoyant plume above the “Deep Hole” hydrothermal system, located southeast of Stevenson Island. Distributed venting in the ~200 × 200‐m hydrothermal field creates a plume with vertical velocities of ~10 cm/s in the mid‐water column. Salinity profiles indicate that during the period of strong summer stratification the plume rises to a neutral buoyancy horizon at ~45‐m depth, corresponding to a ~70‐m rise height, where it generates an anomaly of ~5% (−0.0014 psu) relative to background lake water. We simulate the plume with a numerical model and find that a heat flux of 28 MW reproduces the salinity and vertical velocity observations, corresponding to a mass flux of 1.4 × 103 kg/s. When observational uncertainties are considered, the heat flux could range between 20 to 50 MW., The authors thank Yellowstone National Park Fisheries and Aquatic Sciences, The Global Foundation for Ocean Exploration, and Paul Fucile for logistical support. This research was supported by the National Science Foundation grants EAR‐1516361 to R. S., EAR‐1514865 to K. L., and EAR‐1515283 to R. H. and J. F. All work in Yellowstone National Park was completed under an authorized Yellowstone research permit (YELL‐2018‐SCI‐7018). CTD and ADCP profiles reported in this paper are available through the Marine Geoscience Data System (doi:10.1594/IEDA/324713 and doi:10.1594/IEDA/324712, accessed last on 17 April 2019, respectively)., 2019-11-09

Published
2019

42. Submesoscale processes at shallow salinity fronts in the Bay of Bengal : observations during the winter monsoon

Author

Ramachandran, Sanjiv, Tandon, Amit, MacKinnon, Jennifer A., Lucas, Andrew J., Pinkel, Robert, Waterhouse, Amy F., Nash, Jonathan D., Shroyer, Emily L., Mahadevan, Amala, Weller, Robert A., Farrar, J. Thomas, Ramachandran, Sanjiv, Tandon, Amit, MacKinnon, Jennifer A., Lucas, Andrew J., Pinkel, Robert, Waterhouse, Amy F., Nash, Jonathan D., Shroyer, Emily L., Mahadevan, Amala, Weller, Robert A., and Farrar, J. Thomas

Abstract

Author Posting. © American Meteorological Society, 2018. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Journal of Physical Oceanography 48 (2018): 479-509, doi:10.1175/JPO-D-16-0283.1., Lateral submesoscale processes and their influence on vertical stratification at shallow salinity fronts in the central Bay of Bengal during the winter monsoon are explored using high-resolution data from a cruise in November 2013. The observations are from a radiator survey centered at a salinity-controlled density front, embedded in a zone of moderate mesoscale strain (0.15 times the Coriolis parameter) and forced by winds with a downfront orientation. Below a thin mixed layer, often ≤10 m, the analysis shows several dynamical signatures indicative of submesoscale processes: (i) negative Ertel potential vorticity (PV); (ii) low-PV anomalies with O(1–10) km lateral extent, where the vorticity estimated on isopycnals and the isopycnal thickness are tightly coupled, varying in lockstep to yield low PV; (iii) flow conditions susceptible to forced symmetric instability (FSI) or bearing the imprint of earlier FSI events; (iv) negative lateral gradients in the absolute momentum field (inertial instability); and (v) strong contribution from differential sheared advection at O(1) km scales to the growth rate of the depth-averaged stratification. The findings here show one-dimensional vertical processes alone cannot explain the vertical stratification and its lateral variability over O(1–10) km scales at the radiator survey., S. Ramachandran acknowledges support from the National Science Foundation through award OCE 1558849 and the U.S. Office of Naval Research, Grants N00014-13-1-0456 and N00014-17- 1-2355. A. Tandon acknowledges support from the U.S. Office of Naval Research, Grants N00014-13-1-0456 and N00014-17-1-2355. J. T. Farrar and R. A. Weller were supported by the U.S. Office of Naval Research, Grant N00014-13-1-0453, to collect the UCTD data and process theUCTD and shipboard meteorological data. J. Nash, J. Mackinnon, and A. F. Waterhouse acknowledge support from the U. S. Office of Naval Research, Grants N00014-13-1-0503 and N00014-14-1-0455. E. Shroyer acknowledges support from the U. S. Office of Naval Research, Grants N00014-14-10236 and N00014-15- 12634. A. Mahadevan acknowledges support fromthe U. S. Office of Naval Research, Grant N00014-13-10451. A. J. Lucas and R. Pinkel acknowledge support from the U. S. Office of Naval Research, Grant N00014-13-1-0489., 2018-08-26

Published
2018

43. Inland thinning on the Greenland ice sheet controlled by outlet glacier geometry

Author

Felikson, Denis, Bartholomaus, Timothy C., Catania, Ginny A., Korsgaard, Niels J., Kjær, Kurt H., Morlighem, Mathieu, Noël, Brice, Van Den Broeke, Michiel, Stearns, Leigh A., Shroyer, Emily L., Sutherland, David A., Nash, Jonathan D., Sub Dynamics Meteorology, and Marine and Atmospheric Research

Subjects
Taverne, Earth and Planetary Sciences(all)
Abstract

Greenland's contribution to future sea-level rise remains uncertain and a wide range of upper and lower bounds has been proposed. These predictions depend strongly on how mass loss - which is focused at the termini of marine-terminating outlet glaciers - can penetrate inland to the ice-sheet interior. Previous studies have shown that, at regional scales, Greenland ice sheet mass loss is correlated with atmospheric and oceanic warming. However, mass loss within individual outlet glacier catchments exhibits unexplained heterogeneity, hindering our ability to project ice-sheet response to future environmental forcing. Using digital elevation model differencing, we spatially resolve the dynamic portion of surface elevation change from 1985 to present within 16 outlet glacier catchments in West Greenland, where significant heterogeneity in ice loss exists. We show that the up-glacier extent of thinning and, thus, mass loss, is limited by glacier geometry. We find that 94% of the total dynamic loss occurs between the terminus and the location where the down-glacier advective speed of a kinematic wave of thinning is at least three times larger than its diffusive speed. This empirical threshold enables the identification of glaciers that are not currently thinning but are most susceptible to future thinning in the coming decades.

Published
2017

45. Inland thinning on the Greenland ice sheet controlled by outlet glacier geometry

Author

Sub Dynamics Meteorology, Marine and Atmospheric Research, Felikson, Denis, Bartholomaus, Timothy C., Catania, Ginny A., Korsgaard, Niels J., Kjær, Kurt H., Morlighem, Mathieu, Noël, Brice, Van Den Broeke, Michiel, Stearns, Leigh A., Shroyer, Emily L., Sutherland, David A., Nash, Jonathan D., Sub Dynamics Meteorology, Marine and Atmospheric Research, Felikson, Denis, Bartholomaus, Timothy C., Catania, Ginny A., Korsgaard, Niels J., Kjær, Kurt H., Morlighem, Mathieu, Noël, Brice, Van Den Broeke, Michiel, Stearns, Leigh A., Shroyer, Emily L., Sutherland, David A., and Nash, Jonathan D.

Published
2017

46. ASIRI : an ocean–atmosphere initiative for Bay of Bengal

Author

Wijesekera, Hemantha W., Shroyer, Emily L., Tandon, Amit, Ravichandran, M., Sengupta, Debasis, Jinadasa, S. U. P., Fernando, Harindra J. S., Agrawal, Neeraj, Arulananthan, India K., Bhat, G. S., Baumgartner, Mark F., Buckley, Jared, Centurioni, Luca R., Conry, Patrick, Farrar, J. Thomas, Gordon, Arnold L., Hormann, Verena, Jarosz, Ewa, Jensen, Tommy G., Johnston, T. M. Shaun, Lankhorst, Matthias, Lee, Craig M., Leo, Laura S., Lozovatsky, Iossif, Lucas, Andrew J., MacKinnon, Jennifer A., Mahadevan, Amala, Nash, Jonathan D., Omand, Melissa M., Pham, Hieu, Pinkel, Robert, Rainville, Luc, Ramachandran, Sanjiv, Rudnick, Daniel L., Sarkar, Sutanu, Send, Uwe, Sharma, Rashmi, Simmons, Harper L., Stafford, Kathleen M., St. Laurent, Louis C., Venayagamoorthy, Subhas K., Venkatesan, Ramasamy, Teague, William J., Wang, David W., Waterhouse, Amy F., Weller, Robert A., Whalen, Caitlin B., Wijesekera, Hemantha W., Shroyer, Emily L., Tandon, Amit, Ravichandran, M., Sengupta, Debasis, Jinadasa, S. U. P., Fernando, Harindra J. S., Agrawal, Neeraj, Arulananthan, India K., Bhat, G. S., Baumgartner, Mark F., Buckley, Jared, Centurioni, Luca R., Conry, Patrick, Farrar, J. Thomas, Gordon, Arnold L., Hormann, Verena, Jarosz, Ewa, Jensen, Tommy G., Johnston, T. M. Shaun, Lankhorst, Matthias, Lee, Craig M., Leo, Laura S., Lozovatsky, Iossif, Lucas, Andrew J., MacKinnon, Jennifer A., Mahadevan, Amala, Nash, Jonathan D., Omand, Melissa M., Pham, Hieu, Pinkel, Robert, Rainville, Luc, Ramachandran, Sanjiv, Rudnick, Daniel L., Sarkar, Sutanu, Send, Uwe, Sharma, Rashmi, Simmons, Harper L., Stafford, Kathleen M., St. Laurent, Louis C., Venayagamoorthy, Subhas K., Venkatesan, Ramasamy, Teague, William J., Wang, David W., Waterhouse, Amy F., Weller, Robert A., and Whalen, Caitlin B.

Abstract

Author Posting. © American Meteorological Society, 2016. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Bulletin of the American Meteorological Society 97 (2016): 1859–1884, doi:10.1175/BAMS-D-14-00197.1., Air–Sea Interactions in the Northern Indian Ocean (ASIRI) is an international research effort (2013–17) aimed at understanding and quantifying coupled atmosphere–ocean dynamics of the Bay of Bengal (BoB) with relevance to Indian Ocean monsoons. Working collaboratively, more than 20 research institutions are acquiring field observations coupled with operational and high-resolution models to address scientific issues that have stymied the monsoon predictability. ASIRI combines new and mature observational technologies to resolve submesoscale to regional-scale currents and hydrophysical fields. These data reveal BoB’s sharp frontal features, submesoscale variability, low-salinity lenses and filaments, and shallow mixed layers, with relatively weak turbulent mixing. Observed physical features include energetic high-frequency internal waves in the southern BoB, energetic mesoscale and submesoscale features including an intrathermocline eddy in the central BoB, and a high-resolution view of the exchange along the periphery of Sri Lanka, which includes the 100-km-wide East India Coastal Current (EICC) carrying low-salinity water out of the BoB and an adjacent, broad northward flow (∼300 km wide) that carries high-salinity water into BoB during the northeast monsoon. Atmospheric boundary layer (ABL) observations during the decaying phase of the Madden–Julian oscillation (MJO) permit the study of multiscale atmospheric processes associated with non-MJO phenomena and their impacts on the marine boundary layer. Underway analyses that integrate observations and numerical simulations shed light on how air–sea interactions control the ABL and upper-ocean processes., This work was sponsored by the U.S. Office of Naval Research (ONR) in an ONR Departmental Research Initiative (DRI), Air–Sea Interactions in Northern Indian Ocean (ASIRI), and in a Naval Research Laboratory project, Effects of Bay of Bengal Freshwater Flux on Indian Ocean Monsoon (EBOB). ASIRI–RAWI was funded under the NASCar DRI of the ONR. The Indian component of the program, Ocean Mixing and Monsoons (OMM), was supported by the Ministry of Earth Sciences of India., 2017-04-22

Published
2017

48. Inland thinning on the Greenland ice sheet controlled by outlet glacier geometry

Author

Felikson, Denis, primary, Bartholomaus, Timothy C., additional, Catania, Ginny A., additional, Korsgaard, Niels J., additional, Kjær, Kurt H., additional, Morlighem, Mathieu, additional, Noël, Brice, additional, van den Broeke, Michiel, additional, Stearns, Leigh A., additional, Shroyer, Emily L., additional, Sutherland, David A., additional, and Nash, Jonathan D., additional

Published
2017
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49. Contrasts in the response of adjacent fjords and glaciers to ice-sheet surface melt in West Greenland

Author

Bartholomaus, Timothy C., Stearns, Leigh A., Sutherland, David A., Shroyer, Emily L., Nash, Jonathan D., Walker, Ryan T., Catania, Ginny, Felikson, Denis, Carroll, Dustin, Fried, Mason J., Noël, Brice P.Y., Van Den Broeke, Michiel R., Bartholomaus, Timothy C., Stearns, Leigh A., Sutherland, David A., Shroyer, Emily L., Nash, Jonathan D., Walker, Ryan T., Catania, Ginny, Felikson, Denis, Carroll, Dustin, Fried, Mason J., Noël, Brice P.Y., and Van Den Broeke, Michiel R.

Abstract

Neighboring tidewater glaciers often exhibit asynchronous dynamic behavior, despite relatively uniform regional atmospheric and oceanic forcings. This variability may be controlled by a combination of local factors, including glacier and fjord geometry, fjord heat content and circulation, and glacier surface melt. In order to characterize and understand contrasts in adjacent tidewater glacier and fjord dynamics, we made coincident ice-ocean-atmosphere observations at high temporal resolution (minutes to weeks) within a 10 000 km2 area near Uummannaq, Greenland. Water column velocity, temperature and salinity measurements reveal systematic differences in neighboring fjords that imply contrasting circulation patterns. The observed ocean velocity and hydrography, combined with numerical modeling, suggest that subglacial discharge plays a major role in setting fjord conditions. In addition, satellite remote sensing of seasonal ice flow speed and terminus position reveal both speedup and slow-down in response to melt, as well as differences in calving style among the neighboring glaciers. Glacier force budgets and modeling also point toward subglacial discharge as a key factor in glacier behavior. For the studied region, individual glacier and fjord geometry modulate subglacial discharge, which leads to contrasts in both fjord and glacier dynamics.

Published
2016

50. Contrasts in the response of adjacent fjords and glaciers to ice-sheet surface melt in West Greenland

Author

Sub Dynamics Meteorology, Marine and Atmospheric Research, Bartholomaus, Timothy C., Stearns, Leigh A., Sutherland, David A., Shroyer, Emily L., Nash, Jonathan D., Walker, Ryan T., Catania, Ginny, Felikson, Denis, Carroll, Dustin, Fried, Mason J., Noël, Brice P.Y., Van Den Broeke, Michiel R., Sub Dynamics Meteorology, Marine and Atmospheric Research, Bartholomaus, Timothy C., Stearns, Leigh A., Sutherland, David A., Shroyer, Emily L., Nash, Jonathan D., Walker, Ryan T., Catania, Ginny, Felikson, Denis, Carroll, Dustin, Fried, Mason J., Noël, Brice P.Y., and Van Den Broeke, Michiel R.

Published
2016

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