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1. Indo‐Pacific Sector Dominates Southern Ocean Carbon Outgassing

Author

Prend, Channing J, Gray, Alison R, Talley, Lynne D, Gille, Sarah T, Haumann, F Alexander, Johnson, Kenneth S, Riser, Stephen C, Rosso, Isabella, Sauvé, Jade, and Sarmiento, Jorge L

Subjects
Life Below Water, Climate Action, carbon cycling, air-sea interactions, upper ocean and mixed layer processes, Atmospheric Sciences, Geochemistry, Oceanography, Meteorology & Atmospheric Sciences
Published
2022

3. Future Priorities for Observing the Dynamics of the Southern Ocean.

Author

Wilson, Earle A., Dove, Lilian A., Gray, Alison R., MacGilchrist, Graeme, Purkey, Sarah, Thompson, Andrew F., Youngs, Madeleine, Diggs, Steve, Balwada, Dhruv, Campbell, Ethan C., and Talley, Lynne D.

Subjects
WATER masses, OCEAN surface topography, ATMOSPHERIC sciences, OCEANOGRAPHY, SEA ice drift, ICE shelves
Abstract

The article discusses a workshop funded by the NSF's Office of Polar Programs to address research priorities for observing the dynamics of the Southern Ocean. The Southern Ocean plays a crucial role in global climate, but its dynamics remain uncertain, impacting climate projections. The workshop identified research priorities, such as understanding ice shelf melt rates, sea ice variability, and ocean circulation, and emphasized the need for observational strategies to address these challenges. Additionally, the article highlights the importance of equity, diversity, and inclusion in fieldwork, data management, and international collaboration within the Southern Ocean research community. [Extracted from the article]

Published
2024
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4. Author Correction: Spiraling pathways of global deep waters to the surface of the Southern Ocean.

Author

Tamsitt, Veronica, Drake, Henri F, Morrison, Adele K, Talley, Lynne D, Dufour, Carolina O, Gray, Alison R, Griffies, Stephen M, Mazloff, Matthew R, Sarmiento, Jorge L, Wang, Jinbo, and Weijer, Wilbert

Abstract

The original version of this Article contained errors in Fig. 6. In panel a, the grey highlights obscured the curves for CESM, CM2.6 and SOSE, and the labels indicating SWIR, KP, MR, PAR, and DP were inadvertently omitted. These have now been corrected in both the PDF and HTML versions of the Article.

Published
2018

5. Spiraling pathways of global deep waters to the surface of the Southern Ocean.

Author

Tamsitt, Veronica, Drake, Henri F, Morrison, Adele K, Talley, Lynne D, Dufour, Carolina O, Gray, Alison R, Griffies, Stephen M, Mazloff, Matthew R, Sarmiento, Jorge L, Wang, Jinbo, and Weijer, Wilbert

Abstract

Upwelling of global deep waters to the sea surface in the Southern Ocean closes the global overturning circulation and is fundamentally important for oceanic uptake of carbon and heat, nutrient resupply for sustaining oceanic biological production, and the melt rate of ice shelves. However, the exact pathways and role of topography in Southern Ocean upwelling remain largely unknown. Here we show detailed upwelling pathways in three dimensions, using hydrographic observations and particle tracking in high-resolution models. The analysis reveals that the northern-sourced deep waters enter the Antarctic Circumpolar Current via southward flow along the boundaries of the three ocean basins, before spiraling southeastward and upward through the Antarctic Circumpolar Current. Upwelling is greatly enhanced at five major topographic features, associated with vigorous mesoscale eddy activity. Deep water reaches the upper ocean predominantly south of the Antarctic Circumpolar Current, with a spatially nonuniform distribution. The timescale for half of the deep water to upwell from 30° S to the mixed layer is ~60-90 years.Deep waters of the Atlantic, Pacific and Indian Oceans upwell in the Southern Oceanbut the exact pathways are not fully characterized. Here the authors present a three dimensional view showing a spiralling southward path, with enhanced upwelling by eddy-transport at topographic hotspots.

Published
2017

6. LIGHT-bgcArgo-1.0: using synthetic float capabilities in E3SMv2 to assess spatiotemporal variability in ocean physics and biogeochemistry.

Author

Nissen, Cara, Lovenduski, Nicole S., Maltrud, Mathew, Gray, Alison R., Takano, Yohei, Falcinelli, Kristen, Sauvé, Jade, and Smith, Katherine

Subjects
BIOSENSORS, PROGNOSTIC models, PHYSICS, PROOF of concept, OCEAN
Abstract

Since their advent over 2 decades ago, autonomous Argo floats have revolutionized the field of oceanography, and, more recently, the addition of biogeochemical and biological sensors to these floats has greatly improved our understanding of carbon, nutrient, and oxygen cycling in the ocean. While Argo floats offer unprecedented horizontal, vertical, and temporal coverage of the global ocean, uncertainties remain about whether Argo sampling frequency and density capture the true spatiotemporal variability in physical, biogeochemical, and biological properties. As the true distributions of, e.g., temperature or oxygen are unknown, these uncertainties remain difficult to address with Argo floats alone. Numerical models with synthetic observing systems offer one potential avenue to address these uncertainties. Here, we implement synthetic biogeochemical Argo floats into the Energy Exascale Earth System Model version 2 (E3SMv2), which build on the Lagrangian In Situ Global High-Performance Particle Tracking (LIGHT) module in E3SMv2 (E3SMv2-LIGHT-bgcArgo-1.0). Since the synthetic floats sample the model fields at model run time, the end user defines the sampling protocol ahead of any model simulation, including the number and distribution of synthetic floats to be deployed, their sampling frequency, and the prognostic or diagnostic model fields to be sampled. Using a 6-year proof-of-concept simulation, we illustrate the utility of the synthetic floats in different case studies. In particular, we quantify the impact of (i) sampling density on the float-derived detection of deep-ocean change in temperature or oxygen and on float-derived estimates of phytoplankton phenology, (ii) sampling frequency and sea-ice cover on float trajectory lengths and hence float-derived estimates of current velocities, and (iii) short-term variability in ecosystem stressors on estimates of their seasonal variability. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Using synthetic float capabilities in E3SMv2 to assess spatio-temporal variability in ocean physics and biogeochemistry.

Author

Nissen, Cara, Lovenduski, Nicole S., Maltrud, Mathew, Gray, Alison R., Yohei Takano, Falcinelli, Kristen, Sauvé, Jade, and Smith, Katherine

Subjects
SEA ice, PHYSICS, OCEAN, GLOBAL Ocean Observing System, BIOGEOCHEMISTRY, SPACE sciences
Abstract

The document is a compilation of scientific articles and reports related to oceanography and climate research. The articles cover a wide range of topics including phytoplankton bloom phenology, ocean currents, carbon cycle simulations, sea-ice dynamics, and subsurface chlorophyll concentrations. These articles provide valuable information for researchers studying these specific topics and highlight the importance of ongoing research and monitoring efforts in understanding and predicting changes in the marine environment. [Extracted from the article]

Published
2024
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15. Indo‐Pacific sector dominates Southern Ocean carbon outgassing

Author

Prend, Channing J., Gray, Alison R., Talley, Lynne D., Gille, Sarah T., Haumann, F. Alexander, Johnson, Kenneth S., Riser, Stephen C., Rosso, Isabella, Sauvé, Jade, Sarmiento, Jorge L., Prend, Channing J., Gray, Alison R., Talley, Lynne D., Gille, Sarah T., Haumann, F. Alexander, Johnson, Kenneth S., Riser, Stephen C., Rosso, Isabella, Sauvé, Jade, and Sarmiento, Jorge L.

Abstract

The Southern Ocean modulates the climate system by exchanging heat and carbon dioxide (CO2) between the atmosphere and deep ocean. While this region plays an outsized role in the global oceanic anthropogenic carbon uptake, CO2 is also released to the atmosphere across large swaths of the Antarctic Circumpolar Current (ACC). Southern Ocean outgassing has long been attributed to remineralized carbon from upwelled deep water, but the precise mechanisms by which this water reaches the surface are not well constrained from observations. Using data from a novel array of autonomous biogeochemical profiling floats, we examine Southern Ocean air–sea CO2 fluxes and the pathways that transfer carbon from the ocean interior into the mixed layer where air–sea exchange occurs. These float-based flux estimates of unprecedented spatial resolution indicate that carbon outgassing occurs predominantly in the Indo-Pacific sector of the ACC due to variations in the mean surface ocean partial pressure of CO2 (pCO2). We show that this zonal asymmetry in surface pCO2, and consequently air–sea carbon fluxes, stems primarily from regional variability in the mixed-layer entrainment of upwelled carbon-rich deep water. These results suggest that a sustained circumpolar observing system is crucial to monitor future changes in oceanic carbon release and uptake.

Published
2022

20. Utilizing the Drake Passage Time-series to understand variability and change in subpolar Southern Ocean pCO2

Author

Fay, Amanda R., Lovenduski, Nicole S., Mckinley, Galen A., Munro, David R., Sweeney, Colm, Gray, Alison R., Landschuetzer, Peter, Stephens, Britton B., Takahashi, Taro, and Williams, Nancy

Abstract

The Southern Ocean is highly under-sampled for the purpose of assessing total carbon uptake and its variability. Since this region dominates the mean global ocean sink for anthropogenic carbon, understanding temporal change is critical. Underway measurements of pCO2 collected as part of the Drake Passage Time-series (DPT) program that began in 2002 inform our understanding of seasonally changing air–sea gradients in pCO2, and by inference the carbon flux in this region. Here, we utilize available pCO2 observations to evaluate how the seasonal cycle, interannual variability, and long-term trends in surface ocean pCO2 in the Drake Passage region compare to that of the broader subpolar Southern Ocean. Our results indicate that the Drake Passage is representative of the broader region in both seasonality and long-term pCO2 trends, as evident through the agreement of timing and amplitude of seasonal cycles as well as trend magnitudes both seasonally and annually. The high temporal density of sampling by the DPT is critical to constraining estimates of the seasonal cycle of surface pCO2 in this region, as winter data remain sparse in areas outside of the Drake Passage. An increase in winter data would aid in reduction of uncertainty levels. On average over the period 2002–2016, data show that carbon uptake has strengthened with annual surface ocean pCO2 trends in the Drake Passage and the broader subpolar Southern Ocean less than the global atmospheric trend. Analysis of spatial correlation shows Drake Passage pCO2 to be representative of pCO2 and its variability up to several hundred kilometers away from the region. We also compare DPT data from 2016 and 2017 to contemporaneous pCO2 estimates from autonomous biogeochemical floats deployed as part of the Southern Ocean Carbon and Climate Observations and Modeling project (SOCCOM) so as to highlight the opportunity for evaluating data collected on autonomous observational platforms. Though SOCCOM floats sparsely sample the Drake Passage region for 2016–2017 compared to the Drake Passage Time-series, their pCO2 estimates fall within the range of underway observations given the uncertainty on the estimates. Going forward, continuation of the Drake Passage Time-series will reduce uncertainties in Southern Ocean carbon uptake seasonality, variability, and trends, and provide an invaluable independent dataset for post-deployment assessment of sensors on autonomous floats. Together, these datasets will vastly increase our ability to monitor change in the ocean carbon sink.

Published
2018

22. Global Perspectives on Observing Ocean Boundary Current Systems

Author

Todd, Robert E., primary, Chavez, Francisco P., additional, Clayton, Sophie, additional, Cravatte, Sophie, additional, Goes, Marlos, additional, Graco, Michelle, additional, Lin, Xiaopei, additional, Sprintall, Janet, additional, Zilberman, Nathalie V., additional, Archer, Matthew, additional, Arístegui, Javier, additional, Balmaseda, Magdalena, additional, Bane, John M., additional, Baringer, Molly O., additional, Barth, John A., additional, Beal, Lisa M., additional, Brandt, Peter, additional, Calil, Paulo H. R., additional, Campos, Edmo, additional, Centurioni, Luca R., additional, Chidichimo, Maria Paz, additional, Cirano, Mauro, additional, Cronin, Meghan F., additional, Curchitser, Enrique N., additional, Davis, Russ E., additional, Dengler, Marcus, additional, deYoung, Brad, additional, Dong, Shenfu, additional, Escribano, Ruben, additional, Fassbender, Andrea J., additional, Fawcett, Sarah E., additional, Feng, Ming, additional, Goni, Gustavo J., additional, Gray, Alison R., additional, Gutiérrez, Dimitri, additional, Hebert, Dave, additional, Hummels, Rebecca, additional, Ito, Shin-ichi, additional, Krug, Marjorlaine, additional, Lacan, François, additional, Laurindo, Lucas, additional, Lazar, Alban, additional, Lee, Craig M., additional, Lengaigne, Matthieu, additional, Levine, Naomi M., additional, Middleton, John, additional, Montes, Ivonne, additional, Muglia, Mike, additional, Nagai, Takeyoshi, additional, Palevsky, Hilary I., additional, Palter, Jaime B., additional, Phillips, Helen E., additional, Piola, Alberto, additional, Plueddemann, Albert J., additional, Qiu, Bo, additional, Rodrigues, Regina R., additional, Roughan, Moninya, additional, Rudnick, Daniel L., additional, Rykaczewski, Ryan R., additional, Saraceno, Martin, additional, Seim, Harvey, additional, Gupta, Alex Sen, additional, Shannon, Lynne, additional, Sloyan, Bernadette M., additional, Sutton, Adrienne J., additional, Thompson, LuAnne, additional, Plas, Anja K. van der, additional, Volkov, Denis, additional, Wilkin, John, additional, Zhang, Dongxiao, additional, and Zhang, Linlin, additional

Published
2019
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23. Reassessing Southern Ocean Air-Sea CO2 Flux Estimates With the Addition of Biogeochemical Float Observations

Author

Bushinsky, Seth M., Landschuetzer, Peter, Roedenbeck, Christian, Gray, Alison R., Baker, David, Mazloff, Matthew R., Resplandy, Laure, Johnson, Kenneth S., Sarmiento, Jorge L., Bushinsky, Seth M., Landschuetzer, Peter, Roedenbeck, Christian, Gray, Alison R., Baker, David, Mazloff, Matthew R., Resplandy, Laure, Johnson, Kenneth S., and Sarmiento, Jorge L.

Abstract

New estimates of pCO(2) from profiling floats deployed by the Southern Ocean Carbon and Climate Observations and Modeling (SOCCOM) project have demonstrated the importance of wintertime outgassing south of the Polar Front, challenging the accepted magnitude of Southern Ocean carbon uptake (Gray et al., 2018, ). Here, we put 3.5 years of SOCCOM observations into broader context with the global surface carbon dioxide database (Surface Ocean CO2 Atlas, SOCAT) by using the two interpolation methods currently used to assess the ocean models in the Global Carbon Budget (Le Quere et al., 2018, ) to create a ship-only, a float-weighted, and a combined estimate of Southern Ocean carbon fluxes (<35 degrees S). In our ship-only estimate, we calculate a mean uptake of -1.14 0.19 Pg C/yr for 2015-2017, consistent with prior studies. The float-weighted estimate yields a significantly lower Southern Ocean uptake of -0.35 0.19 Pg C/yr. Subsampling of high-resolution ocean biogeochemical process models indicates that some of the differences between float and ship-only estimates of the Southern Ocean carbon flux can be explained by spatial and temporal sampling differences. The combined ship and float estimate minimizes the root-mean-square pCO(2) difference between the mapped product and both data sets, giving a new Southern Ocean uptake of -0.75 0.22 Pg C/yr, though with uncertainties that overlap the ship-only estimate. An atmospheric inversion reveals that a shift of this magnitude in the contemporary Southern Ocean carbon flux must be compensated for by ocean or land sinks within the Southern Hemisphere. Plain Language Summary The Southern Ocean is thought to take up a significant amount of carbon dioxide each year but is a difficult region to observe due to its remote location and harsh winter weather. Recently, autonomous robots deployed by the Southern Ocean Carbon and Climate Observations and Modeling project have been making year-round measurements of ocean carbonate chemis

Published
2019
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24. Global perspectives on observing ocean boundary current systems

Author

Todd, Robert E., Chavez, Francisco P., Clayton, Sophie A., Cravatte, Sophie, Goes, Marlos Pereira, Graco, Michelle, Lin, Xiaopei, Sprintall, Janet, Zilberman, Nathalie, Archer, Matthew, Arístegui, Javier, Balmaseda, Magdalena A., Bane, John M., Baringer, Molly O., Barth, John A., Beal, Lisa M., Brandt, Peter, Calil, Paulo H. R., Campos, Edmo, Centurioni, Luca R., Chidichimo, Maria Paz, Cirano, Mauro, Cronin, Meghan F., Curchitser, Enrique N., Davis, Russ E., Dengler, Marcus, deYoung, Brad, Dong, Shenfu, Escribano, Ruben, Fassbender, Andrea, Fawcett, Sarah E., Feng, Ming, Goni, Gustavo J., Gray, Alison R., Gutiérrez, Dimitri, Hebert, Dave, Hummels, Rebecca, Ito, Shin-ichi, Krug, Marjolaine, Lacan, Francois, Laurindo, Lucas, Lazar, Alban, Lee, Craig M., Lengaigne, Matthieu, Levine, Naomi M., Middleton, John, Montes, Ivonne, Muglia, Michael, Nagai, Takeyoshi, Palevsky, Hilary I., Palter, Jaime B., Phillips, Helen E., Piola, Alberto R., Plueddemann, Albert J., Qiu, Bo, Rodrigues, Regina, Roughan, Moninya, Rudnick, Daniel L., Rykaczewski, Ryan R., Saraceno, Martin, Seim, Harvey E., Sen Gupta, Alexander, Shannon, Lynne, Sloyan, Bernadette M., Sutton, Adrienne J., Thompson, LuAnne, van der Plas, Anja K., Volkov, Denis L., Wilkin, John L., Zhang, Dongxiao, Zhang, Linlin, Todd, Robert E., Chavez, Francisco P., Clayton, Sophie A., Cravatte, Sophie, Goes, Marlos Pereira, Graco, Michelle, Lin, Xiaopei, Sprintall, Janet, Zilberman, Nathalie, Archer, Matthew, Arístegui, Javier, Balmaseda, Magdalena A., Bane, John M., Baringer, Molly O., Barth, John A., Beal, Lisa M., Brandt, Peter, Calil, Paulo H. R., Campos, Edmo, Centurioni, Luca R., Chidichimo, Maria Paz, Cirano, Mauro, Cronin, Meghan F., Curchitser, Enrique N., Davis, Russ E., Dengler, Marcus, deYoung, Brad, Dong, Shenfu, Escribano, Ruben, Fassbender, Andrea, Fawcett, Sarah E., Feng, Ming, Goni, Gustavo J., Gray, Alison R., Gutiérrez, Dimitri, Hebert, Dave, Hummels, Rebecca, Ito, Shin-ichi, Krug, Marjolaine, Lacan, Francois, Laurindo, Lucas, Lazar, Alban, Lee, Craig M., Lengaigne, Matthieu, Levine, Naomi M., Middleton, John, Montes, Ivonne, Muglia, Michael, Nagai, Takeyoshi, Palevsky, Hilary I., Palter, Jaime B., Phillips, Helen E., Piola, Alberto R., Plueddemann, Albert J., Qiu, Bo, Rodrigues, Regina, Roughan, Moninya, Rudnick, Daniel L., Rykaczewski, Ryan R., Saraceno, Martin, Seim, Harvey E., Sen Gupta, Alexander, Shannon, Lynne, Sloyan, Bernadette M., Sutton, Adrienne J., Thompson, LuAnne, van der Plas, Anja K., Volkov, Denis L., Wilkin, John L., Zhang, Dongxiao, and Zhang, Linlin

Abstract

© The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Todd, R. E., Chavez, F. P., Clayton, S., Cravatte, S., Goes, M., Greco, M., Ling, X., Sprintall, J., Zilberman, N., V., Archer, M., Aristegui, J., Balmaseda, M., Bane, J. M., Baringer, M. O., Barth, J. A., Beal, L. M., Brandt, P., Calil, P. H. R., Campos, E., Centurioni, L. R., Chidichimo, M. P., Cirano, M., Cronin, M. F., Curchitser, E. N., Davis, R. E., Dengler, M., deYoung, B., Dong, S., Escribano, R., Fassbender, A. J., Fawcett, S. E., Feng, M., Goni, G. J., Gray, A. R., Gutierrez, D., Hebert, D., Hummels, R., Ito, S., Krug, M., Lacan, F., Laurindo, L., Lazar, A., Lee, C. M., Lengaigne, M., Levine, N. M., Middleton, J., Montes, I., Muglia, M., Nagai, T., Palevsky, H., I., Palter, J. B., Phillips, H. E., Piola, A., Plueddemann, A. J., Qiu, B., Rodrigues, R. R., Roughan, M., Rudnick, D. L., Rykaczewski, R. R., Saraceno, M., Seim, H., Sen Gupta, A., Shannon, L., Sloyan, B. M., Sutton, A. J., Thompson, L., van der Plas, A. K., Volkov, D., Wilkin, J., Zhang, D., & Zhang, L. Global perspectives on observing ocean boundary current systems. Frontiers in Marine Science, 6, (2010); 423, doi: 10.3389/fmars.2019.00423., Ocean boundary current systems are key components of the climate system, are home to highly productive ecosystems, and have numerous societal impacts. Establishment of a global network of boundary current observing systems is a critical part of ongoing development of the Global Ocean Observing System. The characteristics of boundary current systems are reviewed, focusing on scientific and societal motivations for sustained observing. Techniques currently used to observe boundary current systems are reviewed, followed by a census of the current state of boundary current observing systems globally. The next steps in the development of boundary current observing systems are considered, leading to several specific recommendations., RT was supported by The Andrew W. Mellon Foundation Endowed Fund for Innovative Research at WHOI. FC was supported by the David and Lucile Packard Foundation. MGo was funded by NSF and NOAA/AOML. XL was funded by China’s National Key Research and Development Projects (2016YFA0601803), the National Natural Science Foundation of China (41490641, 41521091, and U1606402), and the Qingdao National Laboratory for Marine Science and Technology (2017ASKJ01). JS was supported by NOAA’s Global Ocean Monitoring and Observing Program (Award NA15OAR4320071). DZ was partially funded by the Joint Institute for the Study of the Atmosphere and Ocean (JISAO) under NOAA Cooperative Agreement NA15OAR4320063. BS was supported by IMOS and CSIRO’s Decadal Climate Forecasting Project. We gratefully acknowledge the wide range of funding sources from many nations that have enabled the observations and analyses reviewed here.

Published
2019

26. Utilizing the Drake Passage Time-series to understand variability and change in subpolar Southern Ocean &lt;i&gt;p&lt;/i&gt;CO&lt;sub&gt;2&lt;/sub&gt;

Author

Fay, Amanda R., primary, Lovenduski, Nicole S., additional, McKinley, Galen A., additional, Munro, David R., additional, Sweeney, Colm, additional, Gray, Alison R., additional, Landschützer, Peter, additional, Stephens, Britton B., additional, Takahashi, Taro, additional, and Williams, Nancy, additional

Published
2018
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27. Autonomous Biogeochemical Floats Detect Significant Carbon Dioxide Outgassing in the High-Latitude Southern Ocean

Author

Gray, Alison R., Johnson, Kenneth S., Bushinsky, Seth M., Riser, Stephen C., Russell, Joellen L., Talley, Lynne D., Wanninkhof, Rik, Williams, Nancy L., Sarmiento, Jorge L., Gray, Alison R., Johnson, Kenneth S., Bushinsky, Seth M., Riser, Stephen C., Russell, Joellen L., Talley, Lynne D., Wanninkhof, Rik, Williams, Nancy L., and Sarmiento, Jorge L.

Abstract

Although the Southern Ocean is thought to account for a significant portion of the contemporary oceanic uptake of carbon dioxide (CO2), flux estimates in this region are based on sparse observations that are strongly biased toward summer. Here we present new estimates of Southern Ocean air-sea CO2 fluxes calculated with measurements from biogeochemical profiling floats deployed by the Southern Ocean Carbon and Climate Observations and Modeling project during 2014-2017. Compared to ship-based CO2 flux estimates, the float-based fluxes find significantly stronger outgassing in the zone around Antarctica where carbon-rich deep waters upwell to the surface ocean. Although interannual variability contributes, this difference principally stems from the lack of autumn and winter ship-based observations in this high-latitude region. These results suggest that our current understanding of the distribution of oceanic CO2 sources and sinks may need revision and underscore the need for sustained year-round biogeochemical observations in the Southern Ocean. Plain Language Summary The Southern Ocean absorbs a great deal of carbon dioxide from the atmosphere and helps to shape the climate of Earth. However, we do not have many observations from this part of the world, especially in winter, because it is remote and inhospitable. Here we present new observations from robotic drifting buoys that take measurements of temperature, salinity, and other water properties year-round. We use these data to estimate the amount of carbon dioxide being absorbed by the Southern Ocean. In the open water region close to Antarctica, the new estimates are remarkably different from the previous estimates, which were based on data collected from ships. We discuss some possible reasons that the float-based estimate is different and how this changes our understanding of how the ocean absorbs carbon dioxide.

Published
2018
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28. Lagrangian timescales of Southern Ocean upwelling in a hierarchy of model resolutions

Author

Drake, Henri F., Morrison, Adele K., Griffies, Stephen M., Sarmiento, Jorge L., Weijer, Wilbert, Gray, Alison R., Drake, Henri F., Morrison, Adele K., Griffies, Stephen M., Sarmiento, Jorge L., Weijer, Wilbert, and Gray, Alison R.

Abstract

Author Posting. © American Geophysical Union, 2018. 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 45 (2018): 891–898, doi:10.1002/2017GL076045., In this paper we study upwelling pathways and timescales of Circumpolar Deep Water (CDW) in a hierarchy of models using a Lagrangian particle tracking method. Lagrangian timescales of CDW upwelling decrease from 87 years to 31 years to 17 years as the ocean resolution is refined from 1° to 0.25° to 0.1°. We attribute some of the differences in timescale to the strength of the eddy fields, as demonstrated by temporally degrading high-resolution model velocity fields. Consistent with the timescale dependence, we find that an average Lagrangian particle completes 3.2 circumpolar loops in the 1° model in comparison to 0.9 loops in the 0.1° model. These differences suggest that advective timescales and thus interbasin merging of upwelling CDW may be overestimated by coarse-resolution models, potentially affecting the skill of centennial scale climate change projections., Department of Energy's RGCM Grant Number: DE-SC0012457; Southern Ocean Carbon and Climate Observation and Modeling Grant Number: PLR-1425989; Climate and Global Change Postdoctoral Fellowship from the National Oceanic and Atmospheric Administration; Australian Research Council DECRA Fellowship Grant Number: DE170100184, 2018-07-31

Published
2018

34. Reassessing Southern Ocean Air‐Sea CO2 Flux Estimates With the Addition of Biogeochemical Float Observations.

Author

Bushinsky, Seth M., Landschützer, Peter, Rödenbeck, Christian, Gray, Alison R., Baker, David, Mazloff, Matthew R., Resplandy, Laure, Johnson, Kenneth S., and Sarmiento, Jorge L.

Subjects
CARBON cycle, OCEAN, FLUX (Energy), AUTONOMOUS robots, CARBON dioxide, ESTIMATES
Abstract

New estimates of pCO2 from profiling floats deployed by the Southern Ocean Carbon and Climate Observations and Modeling (SOCCOM) project have demonstrated the importance of wintertime outgassing south of the Polar Front, challenging the accepted magnitude of Southern Ocean carbon uptake (Gray et al., 2018, https://doi:10.1029/2018GL078013). Here, we put 3.5 years of SOCCOM observations into broader context with the global surface carbon dioxide database (Surface Ocean CO2 Atlas, SOCAT) by using the two interpolation methods currently used to assess the ocean models in the Global Carbon Budget (Le Quéré et al., 2018, https://doi:10.5194/essd‐10‐2141‐2018) to create a ship‐only, a float‐weighted, and a combined estimate of Southern Ocean carbon fluxes (<35°S). In our ship‐only estimate, we calculate a mean uptake of −1.14 ± 0.19 Pg C/yr for 2015–2017, consistent with prior studies. The float‐weighted estimate yields a significantly lower Southern Ocean uptake of −0.35 ± 0.19 Pg C/yr. Subsampling of high‐resolution ocean biogeochemical process models indicates that some of the differences between float and ship‐only estimates of the Southern Ocean carbon flux can be explained by spatial and temporal sampling differences. The combined ship and float estimate minimizes the root‐mean‐square pCO2 difference between the mapped product and both data sets, giving a new Southern Ocean uptake of −0.75 ± 0.22 Pg C/yr, though with uncertainties that overlap the ship‐only estimate. An atmospheric inversion reveals that a shift of this magnitude in the contemporary Southern Ocean carbon flux must be compensated for by ocean or land sinks within the Southern Hemisphere. Plain Language Summary: The Southern Ocean is thought to take up a significant amount of carbon dioxide each year but is a difficult region to observe due to its remote location and harsh winter weather. Recently, autonomous robots deployed by the Southern Ocean Carbon and Climate Observations and Modeling project have been making year‐round measurements of ocean carbonate chemistry, from which we can estimate surface carbon dioxide. These provide new data at times and locations where we previously had very little. We found that combining the float observations with traditional shipboard data reduced our estimate for the amount carbon that the Southern Ocean takes up each year, though by less than had been previously estimated when considering float observations alone. We also show that some of the new signals is likely due to the differences in when and where floats make measurements. The magnitude of difference between prior estimates of the Southern Ocean carbon flux and our new approach is significant, ~20% of the contemporary global ocean carbon flux. It is therefore crucial to understand how this may impact the global carbon cycle, and we show that a compensating flux must be found somewhere within the Southern Hemisphere. Key Points: A combined ship and float carbon dioxide flux estimate for the Southern Ocean yields 0.4 Pg C/yr less uptake than a ship‐only estimateModel subsampling indicates that some of the differences between ship and float flux estimates may be due to sampling times and locationsAn atmospheric inversion using the new ocean fluxes indicates that any compensating flux must be found in land or ocean south of 5°S [ABSTRACT FROM AUTHOR]

Published
2019
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35. Oxygen in the Southern Ocean From Argo Floats: Determination of Processes Driving Air-Sea Fluxes

Author

Bushinsky, Seth M., Gray, Alison R., Johnson, Kenneth S., Sarmiento, Jorge L., Bushinsky, Seth M., Gray, Alison R., Johnson, Kenneth S., and Sarmiento, Jorge L.

Abstract

The Southern Ocean is of outsized significance to the global oxygen and carbon cycles with relatively poor measurement coverage due to harsh winters and seasonal ice cover. In this study, we use recent advances in the parameterization of air-sea oxygen fluxes to analyze 9 years of oxygen data from a recalibrated Argo oxygen data set and from air-calibrated oxygen floats deployed as part of the Southern Ocean Carbon and Climate Observations and Modeling (SOCCOM) project. From this combined data set of 150 floats, we find a total Southern Ocean oxygen sink of -18380 Tmol yr(-1) (positive to the atmosphere), greater than prior estimates. The uptake occurs primarily in the Polar-Frontal Antarctic Zone (PAZ, -9430 Tmol O-2 yr(-1)) and Seasonal Ice Zone (SIZ, -1119.3 Tmol O-2 yr(-1)). This flux is driven by wintertime ventilation, with a large portion of the flux in the SIZ passing through regions with fractional sea ice. The Subtropical Zone (STZ) is seasonally driven by thermal fluxes and exhibits a net outgassing of 4729 Tmol O-2 yr(-1) that is likely driven by biological production. The Subantarctic Zone (SAZ) uptake is -25 +/- 12 Tmol O-2 yr(-1). Total oxygen fluxes were separated into a thermal and nonthermal component. The nonthermal flux is correlated with net primary production and mixed layer depth in the STZ, SAZ, and PAZ, but not in the SIZ where seasonal sea ice slows the air-sea gas flux response to the entrainment of deep, low-oxygen waters.

Published
2017
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36. Observing the Ice‐Covered Weddell Gyre With Profiling Floats: Position Uncertainties and Correlation Statistics.

Author

Chamberlain, Paul M., Talley, Lynne D., Mazloff, Matthew R., Riser, Stephen C., Speer, Kevin, Gray, Alison R., and Schwartzman, Armin

Subjects
OCEAN gyres, SEA ice, ICE sheets, SATELLITE positioning
Abstract

Argo‐type profiling floats do not receive satellite positioning while under sea ice. Common practice is to approximate unknown positions by linearly interpolating latitude‐longitude between known positions before and after ice cover, although it has been suggested that some improvement may be obtained by interpolating along contours of planetary‐geostrophic potential vorticity. Profiles with linearly interpolated positions represent 16% of the Southern Ocean Argo data set; consequences arising from this approximation have not been quantified. Using three distinct data sets from the Weddell Gyre—10‐day satellite‐tracked Argo floats, daily‐tracked RAFOS‐enabled floats, and a particle release simulation in the Southern Ocean State Estimate—we perform a data withholding experiment to assess position uncertainty in latitude‐longitude and potential vorticity coordinates as a function of time since last fix. A spatial correlation analysis using the float data provides temperature and salinity uncertainty estimates as a function of distance error. Combining the spatial correlation scales and the position uncertainty, we estimate uncertainty in temperature and salinity as a function of duration of position loss. Maximum position uncertainty for interpolation during 8 months without position data is 116 ± 148 km for latitude‐longitude and 92 ± 121 km for potential vorticity coordinates. The estimated maximum uncertainty in local temperature and salinity over the entire 2,000‐m profiles during 8 months without position data is 0.66 ∘C and 0.15 psu in the upper 300 m and 0.16 ∘C and 0.01 psu below 300 m. Plain Language Summary: Argo‐type profiling floats do not receive GPS positioning while under sea ice. Current common practice is to approximate the unknown position by linearly interpolating between the known positions before and after ice cover. This linear interpolation is not the true path that these floats follow with under the ice. What is the uncertainty of this linear approximation? Float position and velocity decorrelate with time—meaning the linear approximation of position tends to be worse as time increases. In our paper, we address the question of measurement uncertainty as a function of time by breaking the problem into two pieces: the position uncertainty as a function of time and the measurement uncertainty as a function of position. Combining these statistics, we estimate uncertainty as a function of time of position loss for temperature and salinity as well as surface fluxes derived from the Southern Ocean State Estimate. Key Points: Argo float position uncertainty when lost under sea ice for 8 months was found to be on the order of 100 kmMapping error in salinity and temperature due to 8 months of position loss was found to be 0.15 psu and 0.66 degrees C in the upper oceanMean RMS difference of surface heat and salinity flux between true and interpolated float trajectories was 28.5 W/m2 and 1.8 × 10−3kg·m−2·s−1 [ABSTRACT FROM AUTHOR]

Published
2018
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37. Utilizing the Drake Passage Time-series to understand variability and change in subpolar Southern Ocean pCO2.

Author

Fay, Amanda R., Lovenduski, Nicole S., McKinley, Galen A., Munro, David R., Sweeney, Colm, Gray, Alison R., Landschützer, Peter, Stephens, Britton B., Takahashi, Taro, and Williams, Nancy

Subjects
BIOGEOCHEMICAL cycles, CLIMATE change, CARBON cycle, ATMOSPHERIC carbon dioxide, OCEANOGRAPHY, ATMOSPHERIC sciences
Abstract

The Southern Ocean is highly under-sampled for the purpose of assessing total carbon uptake and its variability. Since this region dominates the mean global ocean sink for anthropogenic carbon, understanding temporal change is critical. Underway measurements of pCO2 collected as part of the Drake Passage Time-series (DPT) program that began in 2002 inform our understanding of seasonally changing air-sea gradients in pCO2, and by inference the carbon flux in this region. Here, we utilize available pCO2 observations to evaluate how the seasonal cycle, interannual variability, and long-term trends in surface ocean pCO2 in the Drake Passage region compare to that of the broader subpolar Southern Ocean. Our results indicate that the Drake Passage is representative of the broader region in both seasonality and long-term pCO2 trends, as evident through the agreement of timing and amplitude of seasonal cycles as well as trend magnitudes both seasonally and annually. The high temporal density of sampling by the DPT is critical to constraining estimates of the seasonal cycle of surface pCO2 in this region, as winter data remain sparse in areas outside of the Drake Passage. An increase in winter data would aid in reduction of uncertainty levels. On average over the period 2002-2016, data show that carbon uptake has strengthened with annual surface ocean pCO2 trends in the Drake Passage and the broader subpolar Southern Ocean less than the global atmospheric trend. Analysis of spatial correlation shows Drake Passage pCO2 to be representative of pCO2 and its variability up to several hundred kilometers away from the region. We also compare DPT data from 2016 and 2017 to contemporaneous pCO2 estimates from autonomous biogeochemical floats deployed as part of the Southern Ocean Carbon and Climate Observations and Modeling project (SOCCOM) so as to highlight the opportunity for evaluating data collected on autonomous observational platforms. Though SOCCOM floats sparsely sample the Drake Passage region for 2016-2017 compared to the Drake Passage Time-series, their pCO2 estimates fall within the range of underway observations given the uncertainty on the estimates. Going forward, continuation of the Drake Passage Time-series will reduce uncertainties in Southern Ocean carbon uptake seasonality, variability, and trends, and provide an invaluable independent dataset for post-deployment assessment of sensors on autonomous floats. Together, these datasets will vastly increase our ability to monitor change in the ocean carbon sink. [ABSTRACT FROM AUTHOR]

Published
2018
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38. Reassessing Southern Ocean Air‐Sea CO2Flux Estimates With the Addition of Biogeochemical Float Observations

Author

Bushinsky, Seth M., Landschützer, Peter, Rödenbeck, Christian, Gray, Alison R., Baker, David, Mazloff, Matthew R., Resplandy, Laure, Johnson, Kenneth S., and Sarmiento, Jorge L.

Abstract

New estimates of pCO2from profiling floats deployed by the Southern Ocean Carbon and Climate Observations and Modeling (SOCCOM) project have demonstrated the importance of wintertime outgassing south of the Polar Front, challenging the accepted magnitude of Southern Ocean carbon uptake (Gray et al., 2018, https://doi:10.1029/2018GL078013). Here, we put 3.5 years of SOCCOM observations into broader context with the global surface carbon dioxide database (Surface Ocean CO2Atlas, SOCAT) by using the two interpolation methods currently used to assess the ocean models in the Global Carbon Budget (Le Quéré et al., 2018, https://doi:10.5194/essd‐10‐2141‐2018) to create a ship‐only, a float‐weighted, and a combined estimate of Southern Ocean carbon fluxes (<35°S). In our ship‐only estimate, we calculate a mean uptake of −1.14 ± 0.19 Pg C/yr for 2015–2017, consistent with prior studies. The float‐weighted estimate yields a significantly lower Southern Ocean uptake of −0.35 ± 0.19 Pg C/yr. Subsampling of high‐resolution ocean biogeochemical process models indicates that some of the differences between float and ship‐only estimates of the Southern Ocean carbon flux can be explained by spatial and temporal sampling differences. The combined ship and float estimate minimizes the root‐mean‐square pCO2difference between the mapped product and both data sets, giving a new Southern Ocean uptake of −0.75 ± 0.22 Pg C/yr, though with uncertainties that overlap the ship‐only estimate. An atmospheric inversion reveals that a shift of this magnitude in the contemporary Southern Ocean carbon flux must be compensated for by ocean or land sinks within the Southern Hemisphere. The Southern Ocean is thought to take up a significant amount of carbon dioxide each year but is a difficult region to observe due to its remote location and harsh winter weather. Recently, autonomous robots deployed by the Southern Ocean Carbon and Climate Observations and Modeling project have been making year‐round measurements of ocean carbonate chemistry, from which we can estimate surface carbon dioxide. These provide new data at times and locations where we previously had very little. We found that combining the float observations with traditional shipboard data reduced our estimate for the amount carbon that the Southern Ocean takes up each year, though by less than had been previously estimated when considering float observations alone. We also show that some of the new signals is likely due to the differences in when and where floats make measurements. The magnitude of difference between prior estimates of the Southern Ocean carbon flux and our new approach is significant, ~20% of the contemporary global ocean carbon flux. It is therefore crucial to understand how this may impact the global carbon cycle, and we show that a compensating flux must be found somewhere within the Southern Hemisphere. A combined ship and float carbon dioxide flux estimate for the Southern Ocean yields 0.4 Pg C/yr less uptake than a ship‐only estimateModel subsampling indicates that some of the differences between ship and float flux estimates may be due to sampling times and locationsAn atmospheric inversion using the new ocean fluxes indicates that any compensating flux must be found in land or ocean south of 5°S

Published
2019
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41. Utilizing the Drake Passage Time-series to understand variability and change in subpolar Southern Ocean pCO2.

Author

Fay, Amanda R., Lovnduski, Nicole S., McKinley, Galen A., Munro, David R., Sweeney, Colm, Gray, Alison R., Landschützer, Peter, Stephens, Britton, Takahashi, Taro, and Williams, Nancy

Subjects
CARBON, BIOGEOCHEMICAL cycles, SEASONAL temperature variations, PONTOONS, CARBON cycle
Abstract

The Southern Ocean is highly under-sampled for the purpose of assessing total carbon uptake and its variability. Since this region dominates the mean global ocean sink for anthropogenic carbon, understanding temporal change is critical. Underway measurements of pCO2 collected as part of the Drake Passage Time-series (DPT) program that began in 2002 inform our understanding of seasonally changing air-sea gradients in pCO2, and by inference the carbon flux in this region. Here, we utilize all available pCO2 observations collected in the subpolar Southern Ocean to evaluate how the seasonal cycle, interannual variability, and long-term trends in surface ocean pCO2 in the Drake Passage region compare to that of the broader subpolar Southern Ocean. Our results indicate that the Drake Passage is representative of the broader region in both seasonality and long term pCO2 trends shown through the agreement of timing and amplitude of seasonal cycles as well as trend magnitudes. The high temporal density of sampling by the DPT is critical to constraining estimates of the seasonal cycle of surface pCO2 in this region, as winter data remain sparse in areas outside of the Drake Passage. From 2002-2015, data show that carbon uptake has strengthened with surface ocean pCO2 trends less than the global atmospheric trend in the Drake Passage and the broader subpolar Southern Ocean. Analysis of spatial correlation shows Drake Passage pCO2 to be representative of pCO2 and its variability up to several hundred kilometers upstream of the region. We also compare DPT data from 2016 and early 2017 to contemporaneous pCO2 estimates from autonomous biogeochemical floats deployed as part of the Southern Ocean Carbon and Climate Observations and Modeling project (SOCCOM) so as to highlight the opportunity for evaluating data collected on autonomous observational platforms. Though SOCCOM floats sparsely sample the Drake Passage region for 2016-2017, their pCO2 estimates typically fall within the range of underway observations. Going forward, continuation of the Drake Passage Time-series will reduce uncertainties in Southern Ocean carbon uptake seasonality, variability, and trends, and provide an invaluable independent dataset for post-deployment quality control of sensors on autonomous floats. Together, these datasets will vastly increase our ability to monitor change in the ocean carbon sink. [ABSTRACT FROM AUTHOR]

Published
2017
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42. Observing System Simulation Experiments for an array of autonomous biogeochemical profiling floats in the Southern Ocean.

Author

Kamenkovich, Igor, Haza, Angelique, Gray, Alison R., Dufour, Carolina O., and Garraffo, Zulema

Abstract

This study uses Observing System Simulation Experiments (OSSEs) to examine the reconstruction of biogeochemical variables in the Southern Ocean from an array of autonomous profiling floats. In these OSSEs, designed to be relevant to the Southern Ocean Carbon and Climate Observation and Modeling (SOCCOM) project, the simulated floats move with oceanic currents and sample dissolved oxygen and inorganic carbon. The annual mean and seasonal cycle of these fields are then reconstructed and compared to the original model fields. The reconstruction skill is quantified with the reconstruction error (RErr), defined as the difference between the reconstructed and actual model fields, weighted by a local measure of the spatiotemporal variability. The square of the RErr is small (<0.5) for 150 floats in most of the domain, which is interpreted to mean that the reconstruction skill is high. An idealized analytical study demonstrates that the RErr depends on the magnitude of the seasonal cycle, spatial gradients, speed of float movement, amplitude of mesoscale variability, and number of floats. These factors explain a large part of the spatial variability in the RErr and can be used to predict the reconstruction skill of the SOCCOM array. Furthermore, our results demonstrate that an array size of 150 floats is a reasonable choice for reconstruction of surface properties and annual-mean 2000 m inventories, with the exception of the seasonal cycle in parts of the Indo-Atlantic, and that doubling this number to 300 results in a very modest increase in the reconstruction skill for dissolved oxygen. [ABSTRACT FROM AUTHOR]

Published
2017
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44. Reassessing Southern Ocean Air-Sea CO 2 Flux Estimates With the Addition of Biogeochemical Float Observations.

Author

Bushinsky SM, Landschützer P, Rödenbeck C, Gray AR, Baker D, Mazloff MR, Resplandy L, Johnson KS, and Sarmiento JL

Abstract

New estimates of p CO 2 from profiling floats deployed by the Southern Ocean Carbon and Climate Observations and Modeling (SOCCOM) project have demonstrated the importance of wintertime outgassing south of the Polar Front, challenging the accepted magnitude of Southern Ocean carbon uptake (Gray et al., 2018, https://doi:10.1029/2018GL078013). Here, we put 3.5 years of SOCCOM observations into broader context with the global surface carbon dioxide database (Surface Ocean CO 2 Atlas, SOCAT) by using the two interpolation methods currently used to assess the ocean models in the Global Carbon Budget (Le Quéré et al., 2018, https://doi:10.5194/essd-10-2141-2018) to create a ship-only, a float-weighted, and a combined estimate of Southern Ocean carbon fluxes (<35°S). In our ship-only estimate, we calculate a mean uptake of -1.14 ± 0.19 Pg C/yr for 2015-2017, consistent with prior studies. The float-weighted estimate yields a significantly lower Southern Ocean uptake of -0.35 ± 0.19 Pg C/yr. Subsampling of high-resolution ocean biogeochemical process models indicates that some of the differences between float and ship-only estimates of the Southern Ocean carbon flux can be explained by spatial and temporal sampling differences. The combined ship and float estimate minimizes the root-mean-square p CO 2 difference between the mapped product and both data sets, giving a new Southern Ocean uptake of -0.75 ± 0.22 Pg C/yr, though with uncertainties that overlap the ship-only estimate. An atmospheric inversion reveals that a shift of this magnitude in the contemporary Southern Ocean carbon flux must be compensated for by ocean or land sinks within the Southern Hemisphere., (©2019. American Geophysical Union. All Rights Reserved.)

Published
2019
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