{"id":313,"date":"2023-10-06T20:41:16","date_gmt":"2023-10-06T20:41:16","guid":{"rendered":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/?page_id=313"},"modified":"2026-04-18T18:41:12","modified_gmt":"2026-04-18T18:41:12","slug":"publications","status":"publish","type":"page","link":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\n

(Italicized<\/em> names indicate my current and former mentees.)<\/p>\n\n\n\n\n

Submitted<\/h4>\n\n

Cohanim, K.<\/em> and A. L. Stewart<\/strong>. Symmetric Instability in the Sub-Ice Shelf Pycnocline. Submitted to Journal of Physical Oceanography.<\/p>\n\n

Finucane, G. and A. L. Stewart<\/strong>. A Theory of Meltwater- Versus Polynya -Dominated Ice Shelf Cavities. Submitted to Geophysical Research Letters.<\/p>\n\n

Han, X.<\/em>, Q. Wang, A. L. Stewart<\/strong>, Z. Wang, Q. Yang, Q. Ni, C. Liu and D. Chen. High coastal eddy activity around Antarctica revealed by SWOT. Submitted to National Science Review.<\/p>\n\n

Jing, T., R. Chen, A. L. Stewart<\/strong> and C. Qiu. Full-Depth Scale-Dependent Eddy Diffusivities in the Kuroshio Extension. Submitted to Journal of Physical Oceanography.<\/p>\n\n

Lim, W.-I., H.-S. Park and A. L. Stewart<\/strong>. Emergent constraint on the future depth of the Atlantic Meridional Overturning Circulation. Submitted to Science Advances.<\/p>\n\n

Lim, W.-I., H.-S. Park and A. L. Stewart<\/strong>. Future weakening of the Atlantic Meridional Overturning Circulation shaped by reduced Labrador Sea winds and salt transport feedback. Submitted to Nature Communications.<\/p>\n\n

Medvedev, A., H. Wei<\/em>, K. C. Armour, K. Srinivasan, A. Solodoch<\/em>, A. L. Stewart<\/strong> and G. E. Manucharyan. Basin-wide sea-surface observations reveal post-2000 emergence of AMOC weakening. Submitted to Nature Geoscience.<\/p>\n\n

Stewart, A. L.<\/strong>, M. K. Youngs<\/em> and C. J. Prend. Fate of heat approaching Antarctica\u2019s largest ice shelves mediated by continental shelf eddies. Submitted to Science Advances.<\/p>\n\n

Wei, H.<\/em>, A. L. Stewart<\/strong>, J. C. McWilliams and E. Capo. Formation of Abyssal Downwelling-Favorable Prograde Flows via Mesoscale Eddy Potential Vorticity Mixing. Submitted to Journal of Physical Oceanography.<\/p>\n\n

Xin, S., R. Chen, J. Mac, Z. Zhang, Q. Geng and A. L. Stewart<\/strong>. A description of spatially local and nonlocal potential energy cascade in the global ocean. Submitted to Journal of Physical Oceanography.<\/p>\n\n

Youngs, M. K.<\/em>, A. L. Stewart<\/strong>, Y. Si<\/em>, A. F. Thompson and M. P. Schodlok. Antarctic ice-shelf basal melt shaped by competing feedbacks. Submitted to Nature Geoscience.<\/p>\n\n

2026<\/h4>\n\n

Chen, R., X. Su, Q. Geng, Z. Zhang, A. L. Stewart<\/strong> and G. Wang. Satellite altimetry reveals spatially nonlocal kinetic energy cascade in the global ocean<\/a>. Science Advances. 2026;12 :eadz0593.<\/p>\n\n

Moorman, R., A. F. Thompson, M. K. Youngs<\/em> and A. L. Stewart<\/strong>. The Antarctic coastal heat budget is dominated by heat loss to land ice melt<\/a>. Science Advances. 2026;12 :eaec7443.<\/p>\n\n

Yeh, C.-Y.<\/em>, A. L. Stewart<\/strong> and J. C. McWilliams. Regimes of Oceanic Mesoscale Energy Dissipation at Western Boundaries<\/a>. Journal of Physical Oceanography. 2026;56 :759–780.<\/p>\n\n

2025<\/h4>\n\n

Han, X.<\/em>, A. L. Stewart<\/strong>, Z. Wang, C. Liu, Q. Yang and D. Chen. Tidal enhancement of Antarctic dense shelf water export via suppression of continental slope mixing<\/a>. Journal of Physical Oceanography. 2025;55 :2179–2195.<\/p>\n\n

Han, X.<\/em>, A. L. Stewart<\/strong>, Z. Wang, Q. Yang, C. Liu and D. Chen. Tidal effects on Antarctic Bottom Water formation in a changing climate<\/a>. Journal of Geophysical Research: Oceans. 2025;130 :e2025JC022443.<\/p>\n\n

Kosty, J.<\/em>, K. X. Zhao<\/em>, A. L. Stewart<\/strong>, D. E. McCoy<\/em>, D. Bianchi, G. E. Manucharyan and D. Menemenlis. Marine mammal-based observations of subsurface-intensified eddies in the seasonally sea ice-covered Southern Ocean<\/a>. Journal of Geophysical Research: Oceans. 2025;130 :e2024JC021781.<\/p>\n\n

Prend, C. J., S. Swart, A. L. Stewart<\/strong>, M. D. du Pleiss, G. E. Manucharyan and A. F. Thompson. Observed regimes of submesoscale dynamics in the Southern Ocean seasonal ice zone<\/a>. Nature Communications. 2025;16 :8344.<\/p>\n\n

Rintoul, S. R., A. L. Stewart<\/strong>, G. C. Johnson, S. Zhou, A. Foppert, Q. Li, A. K. Morrison, A. Silvano, K. L. Gunn, S. Nihashi and S. Aoki. Antarctic Bottom Water in a Changing Climate<\/a>. Nature Reviews Earth \\& Environment. 2025 :1–17.<\/p>\n\n

Spungin, S.<\/em>, Y. Si<\/em> and A. L. Stewart<\/strong>. Observed Seasonality of Mixed-Layer Eddies and Vertical Heat Transport over the Antarctic Continental Shelf<\/a>. Journal of Geophysical Research: Oceans. 2025;130 :e2024JC021564.<\/p>\n\n

Wei, H.<\/em>, K. Srinivasan, A. L. Stewart<\/strong>, A. Solodoch<\/em>, G. E. Manucharyan and A. McC. Hogg. Full-depth Reconstruction of Long-Term Meridional Overturning Circulation Variability from Satellite-Measurable Quantities via Machine Learning<\/a>. Journal of Advances in Modeling Earth Systems. 2025;17 :e2024MS00491.<\/p>\n\n

2024<\/h4>\n\n

Chen, R., Y. Yang, Q. Geng, A. L. Stewart<\/strong>, G. Flierl and J. Wang. A diagnostic framework linking eddy flux ellipse with eddy-mean energy exchange<\/a>. Ocean-Land-Atmosphere Research. 2024;24 :007.<\/p>\n\n

Finucane, G. D.<\/em> and A. L. Stewart<\/strong>. A Predictive Theory for Heat Transport Into Ice Shelf Cavities<\/a>. Geophysical Research Letters. 2024;51 :e2024GL108196.<\/p>\n\n

Han, X.<\/em>, A. L. Stewart<\/strong>, D. Chen, M. Janout, X. Liu, Z. Wang and A. L. Gordon. Circum-Antarctic bottom water formation mediated by tides and topographic waves<\/a>. Nature Communications. 2024;15 :2049.<\/p>\n\n

Jeffree, J., A. McC. Hogg, A. K. Morrison, A. Solodoch<\/em>, A. L. Stewart<\/strong> and R. McGirr. GRACE satellite observations of Antarctic Bottom Water transport variability<\/a>. Journal of Geophysical Research: Oceans. 2024;129 :e2024JC020990.<\/p>\n\n

Meng, S.<\/em>, A. L. Stewart<\/strong> and G. Manucharyan. Circumpolar transport and overturning strength inferred from satellite observables using Deep Learning in an eddying Southern Ocean channel model<\/a>. Journal of Advances in Modeling Earth Systems. 2024;16 :e2024MS004262.<\/p>\n\n

Moscoso, J. E.<\/em>, D. Bianchi and A. L. Stewart<\/strong>. Controls of Cross-Shore Planktonic Ecosystem Structure in an Idealized Eastern Boundary Upwelling System<\/a>. Journal of Geophysical Research: Oceans. 2024;129 :e2023JC020458.<\/p>\n\n

Si, Y.<\/em>, A. L. Stewart<\/strong>, A. Silvano and A. C. Naveira Garabato. Antarctic slope undercurrent and onshore heat transport driven by ice shelf melting<\/a>. Science Advances. 2024;10 :eadl0601.<\/p>\n\n

Stewart, A. L.<\/strong>, Y. Wang<\/em>, A. Solodoch<\/em>, R. Chen and J. C. McWilliams. Formation of eastern boundary undercurrents via mesoscale eddy rectification<\/a>. Journal of Physical Oceanography. 2024;54 :1765–1785.<\/p>\n\n

2023<\/h4>\n\n

Han, X.<\/em>, A. L. Stewart<\/strong>, D. Chen, X. Liu and T. Lian. Controls of topographic Rossby wave properties and downslope transport in dense overflows<\/a>. Journal of Physical Oceanography. 2023;53 :1805–1820.<\/p>\n\n

Jagannathan, A., K. Srinivasan, J. C. McWilliams, M. J. Molemaker and A. L. Stewart<\/strong>. Evolution of bottom boundary layers on three dimensional topography — Buoyancy adjustment and instabilities<\/a>. Journal of Geophysical Research: Oceans. 2023;128 :e2023JC019705.<\/p>\n\n

Jeong, H., S.-S. Lee, H.-S. Park and A. L. Stewart<\/strong>. Future changes in Antarctic coastal polynyas and bottom water formation simulated by a high-resolution coupled model<\/a>. Communications in Earth and Environment. 2023;4 :490.<\/p>\n\n

Schmidgall, C. R.<\/em>, Y. Si<\/em>, A. L. Stewart<\/strong>, A. F. Thompson and A. McC. Hogg. Dynamical Controls on Bottom Water Transport and Transformation across the Antarctic Circumpolar Current<\/a>. Journal of Physical Oceanography. 2023;53 :1917–1940.<\/p>\n\n

Si, Y.<\/em>, A. L. Stewart<\/strong> and I. Eisenman. Heat transport across the Antarctic Slope Front controlled by cross-slope salinity gradients<\/a>. Science Advances. 2023;9 :eadd7049.<\/p>\n\n

Silvano, A., S. Purkey, P. Castagno, A. L. Stewart<\/strong>, S. Rintoul, A. Foppert, S. Aoki, A. C. Naveira Garabato, C. H. Akhoudas, J.-B. Sall\u00e9e, A. L. Gordon, E. P. Abrahamsen, A. J. S. Meijers, M. P. Meredith, S. Zhou, T. Tamura, K. I. Ohshima, P. Falco, G. Budillon, T. Hattermann, M. A. Janout, H. H. Hellmer, M. M. Bowen, E. Darelius, S. \u00d8sterhus, K. Nicholls, C. Stevens, L. Cimoli, G. D. Williams, A. Morrison and A. McC. Hogg. Observing Antarctic Bottom Water in the Southern Ocean<\/a>. Frontiers in Marine Science. 2023;10 :1221701.<\/p>\n\n

Solodoch, A.<\/em>, A. L. Stewart<\/strong>, A. McC. Hogg and G. Manucharyan. Machine Learning-Derived Inference of the Meridional Overturning Circulation from Satellite-Observable Variables in an Ocean State Estimate<\/a>. Journal of Advances in Modeling Earth Systems. 2023;15 :e2022MS003370.<\/p>\n\n

Stewart, A. L.<\/strong>, N. K. Neumann<\/em> and A. Solodoch<\/em>. “Eddy” saturation of the Antarctic Circumpolar Current by standing waves<\/a>. Journal of Physical Oceanography. 2023;53 :1161–1181.<\/p>\n\n

Zhao, K. X.<\/em>, A. L. Stewart<\/strong>, J. C. McWillliams, I. G. Fenty and E. J. Rignot. Standing Eddies in Glacial Fjords and their Role in Fjord Circulation and Melt<\/a>. Journal of Physical Oceanography. 2023;53 :821–840.<\/p>\n\n

2022<\/h4>\n\n

Wilson, E. A., A. F. Thompson, A. L. Stewart<\/strong> and S. Sun<\/em>. Bottom-up control of subpolar gyres and the overturning circulation in the Southern Ocean<\/a>. Journal of Physical Oceanography. 2022;52 :205–223.<\/p>\n\n

Han, X.<\/em>, A. L. Stewart<\/strong>, D. Chen, T. Lian, X. Liu and X. Xie. Topographic Rossby Wave-modulated oscillations of dense overflows<\/a>. Journal of Geophysical Research: Oceans. 2022;127 :e2022JC018702.<\/p>\n\n

Lim, W.-I., H.-S. Park, A. L. Stewart<\/strong> and K.-H. Seo. Suppression of Arctic sea ice growth in the Eurasian-Pacific Seas by winter clouds and snowfall<\/a>. Journal of Climate. 2022;35 :669–686.<\/p>\n\n

Manucharyan, G. E. and A. L. Stewart<\/strong>. Stirring of Interior Potential Vorticity Gradients as a Formation Mechanism for Large Subsurface-Intensified Eddies in the Beaufort Gyre<\/a>. Journal of Physical Oceanography. 2022;52 :3349–3370.<\/p>\n\n

Moscoso, J. E.<\/em>, D. Bianchi and A. L. Stewart<\/strong>. Controls and characteristics of biomass quantization in size-structured planktonic ecosystem models<\/a>. Ecological Modelling. 2022;468 :109907.<\/p>\n\n

Si, Y.<\/em>, A. L. Stewart<\/strong> and I. Eisenman. Coupled ocean\/sea ice dynamics of the Antarctic Slope Current driven by topographic eddy suppression and sea ice momentum redistribution<\/a>. Journal of Physical Oceanography. 2022;52 :1563–1589.<\/p>\n\n

Silvano, A., P. Holland, K. A. Naughten, O. Dragomir, P. Dutrieux, A. Jenkins, Y. Si<\/em>, A. L. Stewart<\/strong>, B. Pe\u00f1a-Molino, J. Janzing, T. S. Dotto and A. C. Naveira Garabato. Baroclinic ocean response to climate forcing regulates decadal variability of ice-shelf melting in the Amundsen Sea<\/a>. Geophysical Research Letters. 2022;49 :e2022GL100646.<\/p>\n\n

Solodoch, A.<\/em>, A. L. Stewart<\/strong>, A. McC. Hogg, A. K. Morrison, A. E. Kiss, A. F. Thompson, S. G. Purkey and L. Cimoli. How does Antarctic Bottom Water Cross the Southern Ocean?<\/a>. Geophysical Research Letters. 2022 :e2021GL097211.<\/p>\n\n

Stewart, A. L.<\/strong> and J. C. McWilliams. Gravity is Vertical in Geophysical Fluid Dynamics<\/a>. Scientific Reports. 2022 :6029.<\/p>\n\n

Wei, H.<\/em>, Y. Wang<\/em>, A. L. Stewart<\/strong> and J. Mak. Scalings for eddy buoyancy fluxes across prograde shelf\/slope fronts<\/a>. Journal of Advances in Modeling Earth Systems. 2022;14 :e2022MS003229.<\/p>\n\n

Zhao, K. X.<\/em>, A. L. Stewart<\/strong> and J. C. McWillliams. Linking Overturning, Recirculation, and Melt in Glacial Fjords<\/a>. Geophysical Research Letters. 2022;49 :e2021GL097211.<\/p>\n\n

2021<\/h4>\n\n

Bai, Y.<\/em>, Y. Wang<\/em> and A. L. Stewart<\/strong>. Does Topographic Form Stress Impede Prograde Ocean Flows?<\/a>. Journal of Physical Oceanography. 2021;51 :2617–2638.<\/p>\n\n

Cohanim, K.<\/em>, K. X. Zhao<\/em> and A. L. Stewart<\/strong>. Dynamics of Eddies Generated by Sea Ice Leads<\/a>. Journal of Physical Oceanography. 2021;51 :3071–3092.<\/p>\n\n

Jagannathan, A., K. Srinivasan, J. C. McWilliams, M. J. Molemaker and A. L. Stewart<\/strong>. Boundary layer-mediated vorticity generation in currents over sloping bathymetry<\/a>. Journal of Physical Oceanography. 2021;51 :1757–1778.<\/p>\n\n

Moscoso, J. E.<\/em>, A. L. Stewart<\/strong>, D. Bianchi and J. C. McWilliams. The Meridionally Averaged Model of Eastern Boundary Upwelling Systems (MAMEBUSv1.0)<\/a>. Geoscientific Model Development. 2021;14 :763–794.<\/p>\n\n

Solodoch, A.<\/em>, A. L. Stewart<\/strong> and J. C. McWilliams. Formation of anticyclones above topographic depressions<\/a>. Journal of Physical Oceanography. 2021;51 :207–228.<\/p>\n\n

Stewart, A. L.<\/strong>. Mesoscale, tidal and seasonal\/interannual drivers of the Weddell Sea overturning circulation<\/a>. Journal of Physical Oceanography. 2021;51 :3695–3722.<\/p>\n\n

Stewart, A. L.<\/strong>, X. Chi<\/em>, A. Solodoch<\/em> and A. McC. Hogg. High-frequency fluctuations in Antarctic Bottom Water transport driven by Southern Ocean winds<\/a>. Geophysical Research Letters. 2021;8 :e2021GL094569.<\/p>\n\n

Stewart, A. L.<\/strong>, J. C. McWilliams and A. Solodoch<\/em>. On the role of bottom pressure torques in wind-driven gyres<\/a>. Journal of Physical Oceanography. 2021;51 :1441–1464.<\/p>\n\n

Zhao, K. X.<\/em>, A. L. Stewart<\/strong> and J. C. McWilliams. Geometric Constraints on Glacial Fjord\u2013Shelf Exchange<\/a>. Journal of Physical Oceanography. 2021;51 :207–228.<\/p>\n\n

2020<\/h4>\n\n

Hazel, J. E.<\/em> and A. L. Stewart<\/strong>. Bi-stability of the Filchner-Ronne Ice Shelf Cavity Circulation and Basal Melt<\/a>. Journal of Geophysical Research: Oceans. 2020;125 :e2019JC015848.<\/p>\n\n

McCoy, D. E.<\/em>, D. Bianchi and A. L. Stewart<\/strong>. Global Observations of Submesoscale Coherent Vortices in the Ocean<\/a>. Progress in Oceanography. 2020;189 :102452.<\/p>\n\n

Solodoch, A.<\/em>, J. C. McWilliams and A. L. Stewart<\/strong>. Why Does the Deep Western Boundary Current “Leak” Around Flemish Cap?<\/a>. Journal of Physical Oceanography. 2020;50 :1989–2016.<\/p>\n\n

Sun, S.<\/em>, I. Eisenman, L. Zanna and A. L. Stewart<\/strong>. Surface constraints on the depth of the Atlantic Meridional Overturning Circulation: Southern Ocean vs North Atlantic<\/a>. Journal of Climate. 2020;33 :3125-3149.<\/p>\n\n

Wang, Y.<\/em> and A. L. Stewart<\/strong>. Scalings for eddy buoyancy transfer across continental slopes under retrograde winds<\/a>. Ocean Modelling. 2020;147 :101579.<\/p>\n\n

2019<\/h4>\n\n

Hazel, J. E.<\/em> and A. L. Stewart<\/strong>. Multi-Decadal Trends in Easterly Wind Stress around the Antarctic Coast<\/a>. Journal of Climate. 2019;32 :1895–1918.<\/p>\n\n

Park, H.-S., S.-J. Kim, A. L. Stewart<\/strong>, S.-W. Son and K.-H.. Seo. Mid-Holocene Northern Hemisphere warming driven by Arctic amplification and sea ice loss<\/a>. Science Advances. 2019;5 (12).<\/p>\n\n

Stewart, A. L.<\/strong>. Approximating isoneutral ocean transport via the\nTemporal Residual Mean<\/a>. Fluids. 2019;4 :179.<\/p>\n\n

Stewart, A. L.<\/strong>, A. Klocker and D. Menemenlis. Acceleration and overturning of the Antarctic Slope Current by winds, eddies, and tides<\/a>. Journal of Physical Oceanography. 2019;43 :2043–2074.<\/p>\n\n

Zhao, K. X.<\/em>, A. L. Stewart<\/strong> and J. C. McWilliams. Sill-Influenced Exchange Flows in Ice Shelf Cavities<\/a>. Journal of Physical Oceanography. 2019;49 :163–191.<\/p>\n\n

2018<\/h4>\n\n

Park, H.-S., S.-J. Kim, K.-H. Seo, A. L. Stewart<\/strong> and S.-Y. Kim. The impact of Arctic sea ice loss on mid-Holocene climate<\/a>. Nature Communications. 2018;9 :4571.<\/p>\n\n

Park, H.-S., A. L. Stewart<\/strong> and J.-H. Son. Dynamic and thermodynamic impacts of the winter Arctic Oscillation on summer sea ice extent<\/a>. Journal of Climate. 2018;31 :1483–1497.<\/p>\n\n

Stewart, A. L.<\/strong>, A. Klocker and D. Menemenlis. Circum-Antarctic shoreward heat transport derived from an eddy- and tide-resolving simulation<\/a>. Geophysical Research Letters. 2018;45 :834–845.<\/p>\n\n

Sun, S.<\/em>, I. Eisenman and A. L. Stewart<\/strong>. Does Southern Ocean surface forcing shape the global ocean overturning\ncirculation?<\/a>. Geophysical Research Letters. 2018;45 :2413–2423.<\/p>\n\n

Thompson, A. F., A. L. Stewart<\/strong>, P. Spence and K. J. Heywood. The Antarctic Slope Front in a Changing Climate<\/a>. Reviews of Geophysics. 2018;56 :741–770.<\/p>\n\n

Wang, Y.<\/em> and A. L. Stewart<\/strong>. Eddy Dynamics over Continental Slopes under Retrograde Winds: Insights from a Model Inter-Comparison<\/a>. Ocean Modelling. 2018;121 :1–18.<\/p>\n\n

2017<\/h4>\n\n

Stewart, A. L.<\/strong> and A. McC. Hogg. Reshaping the Antarctic Circumpolar Current via Antarctic Bottom Water export<\/a>. Journal of Physical Oceanography. 2017;47 :2577–2601.<\/p>\n\n

2016<\/h4>\n\n

Park, H.-S. and A. L. Stewart<\/strong>. An analytical model for wind-driven Arctic summer sea ice drift<\/a>. The Cryosphere. 2016;10 :227–244.<\/p>\n\n

Solodoch, A.<\/em>, A. L. Stewart<\/strong> and J. C. McWilliams.. Baroclinic instability of axially-symmetric flow over sloping bathymetry<\/a>. Journal of Fluid Mechanics. 2016;799 :265–296.<\/p>\n\n

Stewart, A. L.<\/strong> and P. J. Dellar. An energy and potential enstrophy conserving numerical scheme for the multi-layer shallow water equations with complete Coriolis force<\/a>. Journal of Computational Physics. 2016;313 :99–120.<\/p>\n\n

Stewart, A. L.<\/strong> and A. F. Thompson. Eddy generation and jet formation via dense water outflows across the Antarctic continental slope<\/a>. Journal of Physical Oceanography. 2016;46 :3729–3750.<\/p>\n\n

Su, Z.<\/em>, A. Ingersoll, A. L. Stewart<\/strong> and A. F. Thompson. Ocean Convective Available Potential Energy. Part I: Concept and Calculation<\/a>. Journal of Physical Oceanography. 2016;46 :1081–1096.<\/p>\n\n

Su, Z.<\/em>, A. Ingersoll, A. L. Stewart<\/strong> and A. F. Thompson. Ocean Convective Available Potential Energy. Part II:\nEnergetics of Thermobaric Convection<\/a>. Journal of Physical Oceanography. 2016;46 :1097–1115.<\/p>\n\n

Sun, S.<\/em>, I. Eisenman and A. L. Stewart<\/strong>. Southern Ocean surface buoyancy forcing controls glacial-interglacial changes in the global deep ocean stratification<\/a>. Geophysical Research Letters. 2016;43 :8124–8132.<\/p>\n\n

Thompson, A. F., A. L. Stewart<\/strong> and T. Bischoff. A multi-basin residual-mean model for the global overturning circulation<\/a>. Journal of Physical Oceanography. 2016;46 :2583–2604.<\/p>\n\n

2015<\/h4>\n\n

Burke, A., A. L. Stewart<\/strong>, J. F. Adkins, R. Ferrari, M. F. Jansen and A. F. Thompson. The glacial mid-depth radiocarbon bulge and its implications for the overturning circulation<\/a>. Paleoceanography. 2015;30 :1021–1039.<\/p>\n\n

Stewart, A. L.<\/strong> and A. F. Thompson. Eddy-mediated transport of warm Circumpolar Deep Water across the Antarctic Shelf Break<\/a>. Geophysical Research Letters. 2015;42 :432–440.<\/p>\n\n

Stewart, A. L.<\/strong> and A. F. Thompson. The Neutral Density Temporal Residual Mean overturning circulation<\/a>. Ocean Modelling. 2015;90 :44–56.<\/p>\n\n

Tsai, V. C., A. L. Stewart<\/strong> and A. F. Thompson. Marine ice-sheet profiles and stability under Coulomb basal conditions<\/a>. Journal of Glaciology. 2015;61 (226) :205.<\/p>\n\n

2014<\/h4>\n\n

Ferrari, R., M. F. Jansen, J. F. Adkins, A. Burke, A. L. Stewart<\/strong> and A. F. Thompson. Antarctic sea ice control on ocean circulation in present and glacial climates<\/a>. Proceedings of the National Academy of Sciences. 2014;111 (24) :8753–8758.<\/p>\n\n

Stewart, A. L.<\/strong>, P. J. Dellar and E. R. Johnson. Large-Amplitude Coastal Shelf Waves<\/a>. Modeling Atmospheric and Oceanic Flows. 2014 :229–253.<\/p>\n\n

Stewart, A. L.<\/strong>, R. Ferrari and A. F. Thompson. On the importance of surface forcing in conceptual models of the deep ocean<\/a>. Journal of Physical Oceanography. 2014;44 (3) :891–899.<\/p>\n\n

Su, Z.<\/em>, A. L. Stewart<\/strong> and A. F. Thompson. An idealized model of Weddell Gyre export variability<\/a>. Journal of Physical Oceanography. 2014;44 (6) :1671–1688.<\/p>\n\n

Thompson, A. F., K. J. Heywood, S. Schmidtko and A. L. Stewart<\/strong>. Eddy transport as a key component of the Antarctic overturning circulation<\/a>. Nature Geoscience. 2014;7 (12) :879–884.<\/p>\n\n

2013<\/h4>\n\n

Stewart, A. L.<\/strong> and P. J. Dellar. Multilayer shallow water equations with complete Coriolis force. Part\n3. Hyperbolicity and stability under shear<\/a>. Journal of Fluid Mechanics. 2013;723 :289–317.<\/p>\n\n

Stewart, A. L.<\/strong> and A. F. Thompson. Connecting Antarctic Cross-Slope Exchange with Southern Ocean Overturning<\/a>. Journal of Physical Oceanography. 2013;43 :1453–1471.<\/p>\n\n

2012<\/h4>\n\n

Stewart, A. L.<\/strong> and P. J. Dellar. Cross-equatorial channel flow with zero potential vorticity under the complete Coriolis force<\/a>. IMA Journal of Applied Mathematics. 2012;77 :626–651.<\/p>\n\n

Stewart, A. L.<\/strong> and P.J. Dellar. Multilayer shallow water equations with complete Coriolis force. Part 2. Linear plane waves<\/a>. Journal of Fluid Mechanics. 2012;690 :16–50.<\/p>\n\n

Stewart, A. L.<\/strong> and A. F. Thompson. Sensitivity of the ocean’s deep overturning circulation to easterly Antarctic winds<\/a>. Geophysical Research Letters. 2012;39 (18) :L18604.<\/p>\n\n

2011<\/h4>\n\n

Stewart, A. L.<\/strong> and P. J. Dellar. Cross-equatorial flow through an abyssal channel under the complete Coriolis force: two dimensional solutions<\/a>. Ocean Modelling. 2011;40 :87–104.<\/p>\n\n

Stewart, A. L.<\/strong>, P. J. Dellar and E. R. Johnson. Numerical simulation of wave propagation along a discontinuity in depth in a rotating annulus<\/a>. Computers \\& Fluids. 2011;46 :442–447.<\/p>\n\n

Stewart, A. L.<\/strong> and P.J. Dellar. The role of the complete Coriolis force in \ncross-equatorial flow of abyssal ocean currents<\/a>. Ocean Modelling. 2011;38 :187–202.<\/p>\n\n

2010<\/h4>\n\n

Stewart, A. L.<\/strong> and P. J. Dellar. Multilayer shallow water equations with complete Coriolis force. Part I. Derivation on a non-traditional beta-plane<\/a>. Journal of Fluid Mechanics. 2010;651 :387–413.<\/p>\n\n

Gray Matter<\/h4>\n\n

Chang, E. K. M., C. L. P. Wolfe, A. L. Stewart<\/strong> and J. C. McWilliams. Comments on “Horizontal gravity disturbance vector in atmospheric dynamics” by Peter C. Chu<\/a>. Dynamics of Atmospheres and Oceans. 2023;103 :101382.<\/p>\n\n

Stewart, A. L.<\/strong>. Nonlinear shelf waves in a rotating annulus<\/a>. Technical Report of the 2009 Geophysical Fluid Dynamics Program at Woods Hole Oceanographic Institution. 2010.<\/p>\n\n

Stewart, A. L.<\/strong>. Oceanography: Mixed up at the sea floor<\/a>. Nature. 2017;551 (7679) :178–179.<\/p>\n\n

Stewart, A. L.<\/strong>. Physical oceanography: Warming spins up the Southern Ocean<\/a>. Nature Climate Change. 2021;11 :1022–1024.<\/p>\n\n

Stewart, A. L.<\/strong>. The role of the complete Coriolis force in cross-equatorial transport of abyssal ocean currents<\/a>. 2011.<\/p>\n\n

Stewart, A. L.<\/strong> and P. J. Dellar. Two-layer shallow water equations with complete Coriolis force and topography<\/a>. Progress in Industrial Mathematics at ECMI 2008. 2010 :1033–1038.<\/p>\n\n","protected":false},"excerpt":{"rendered":"

(Italicized names indicate my current and former mentees.) Submitted Cohanim, K. and A. L. Stewart. Symmetric Instability in the Sub-Ice Shelf Pycnocline. Submitted to Journal of Physical Oceanography. Finucane, G. and A. L. Stewart. A Theory of Meltwater- Versus Polynya -Dominated Ice Shelf Cavities. Submitted to Geophysical Research Letters. Han, X., Q. Wang, A. L….<\/p>\n","protected":false},"author":3,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"custom-template-one.php","meta":{"footnotes":""},"class_list":["post-313","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/pages\/313","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/users\/3"}],"replies":[{"embeddable":true,"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/comments?post=313"}],"version-history":[{"count":15,"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/pages\/313\/revisions"}],"predecessor-version":[{"id":644,"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/pages\/313\/revisions\/644"}],"wp:attachment":[{"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/media?parent=313"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}