{"id":613,"date":"2026-02-06T06:29:57","date_gmt":"2026-02-06T06:29:57","guid":{"rendered":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/?page_id=613"},"modified":"2026-03-06T23:13:02","modified_gmt":"2026-03-06T23:13:02","slug":"curriculum-vitae","status":"publish","type":"page","link":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/curriculum-vitae\/","title":{"rendered":"Curriculum Vitae"},"content":{"rendered":"\n

(This is an automated HTML version of my LaTeX CV, generated using Python<\/a> and Pandoc<\/a><\/em>, with a little help from ChatGPT<\/a>. Please contact me<\/a> for a PDF version of my CV.) <\/em><\/p>\n\n\n

Andrew Stewart 2026-03-06<\/h2>\n
\n

Professor
\nDepartment of Atmospheric and Oceanic Sciences
\nUniversity of California, Los Angeles
\nLos Angeles, CA 90095
\n1-310-825-1751
\n<\/p>\n

Employment<\/h2>\n
\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
Jul 2023 \u2013 Present<\/td>\nProfessor<\/td>\n<\/tr>\n
<\/td>\nDepartment of Atmospheric and Oceanic Sciences<\/td>\n<\/tr>\n
<\/td>\nUniversity of California, Los Angeles<\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/tr>\n
Jul 2020 \u2013 Jun 2023<\/td>\nAssociate Professor<\/td>\n<\/tr>\n
<\/td>\nDepartment of Atmospheric and Oceanic Sciences<\/td>\n<\/tr>\n
<\/td>\nUniversity of California, Los Angeles<\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/tr>\n
Jul 2014 \u2013 Jun 2020<\/td>\nAssistant Professor<\/td>\n<\/tr>\n
<\/td>\nDepartment of Atmospheric and Oceanic Sciences<\/td>\n<\/tr>\n
<\/td>\nUniversity of California, Los Angeles<\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/tr>\n
Oct 2011 \u2013 Jun 2014<\/td>\nPostdoctoral Researcher in Environmental Science and Engineering<\/td>\n<\/tr>\n
<\/td>\nDivision of Geological and Planetary Sciences<\/td>\n<\/tr>\n
<\/td>\nCalifornia Institute of Technology<\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/tr>\n
Apr 2011 \u2013 Sep 2011<\/td>\nEPSRC PhD Plus Postdoctoral Researcher<\/td>\n<\/tr>\n
<\/td>\nOxford Centre for Industrial and Applied Mathematics<\/td>\n<\/tr>\n
<\/td>\nUniversity of Oxford<\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/tr>\n
Oct 2010 \u2013 Sep 2011<\/td>\nCollege Lecturer in Applied Mathematics<\/td>\n<\/tr>\n
<\/td>\nCorpus Christi College<\/td>\n<\/tr>\n
<\/td>\nUniversity of Oxford<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Education<\/h2>\n
\n\n\n\n\n\n\n\n\n\n\n\n\n
Oct 2007 \u2013 Mar 2011<\/td>\nCorpus Christi College, University of Oxford<\/td>\n<\/tr>\n
<\/td>\nDPhil in Mathematics<\/em><\/td>\n<\/tr>\n
<\/td>\n\u2018The role of the complete Coriolis force in cross-equatorial transport<\/em><\/td>\n<\/tr>\n
<\/td>\nof abyssal ocean currents\u2019<\/em><\/td>\n<\/tr>\n
<\/td>\nSupported by an EPSRC DTA award.<\/em><\/td>\n<\/tr>\n
<\/td>\nReceived leave to supplicate on 12th<\/sup> July 2011.<\/em><\/td>\n<\/tr>\n
<\/td>\nDegree formally conferred on November 9th<\/sup>, 2013.<\/em><\/td>\n<\/tr>\n
<\/td>\n<\/td>\n<\/tr>\n
Sep 2003 \u2013 Jun 2007<\/td>\nUniversity of St Andrews<\/td>\n<\/tr>\n
<\/td>\nMMath in Mathematics (1st<\/sup> Class)<\/em><\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Peer-Reviewed Publications<\/h2>\n
\n
    \n

  1. M.\u00a0K. Youngs, A.\u00a0L. Stewart, Y.\u00a0Si, A.\u00a0F. Thompson, and M.\u00a0P. Schodlok. Quantifying climatic forcing versus meltwater feedbacks on the Antarctic Ice Shelf melt<\/span>. Submitted to<\/em><\/span> Nature Geoscience<\/em><\/span>.<\/p><\/li>\n

  2. W.-I. Lim, H.-S. Park, and A.\u00a0L. Stewart. Emergent constraint on the future depth of the Atlantic Meridional Overturning Circulation<\/span>. Submitted to<\/em><\/span> Nature Geoscience<\/em><\/span>.<\/p><\/li>\n

  3. S.\u00a0Xin, R.\u00a0Chen, J.\u00a0Mac, Z.\u00a0Zhang, Q.\u00a0Geng, and A.\u00a0L. Stewart. A description of spatially local and nonlocal potential energy cascade in the global ocean<\/span>. Submitted to<\/em><\/span> Journal of Physical Oceanography<\/em><\/span>.<\/p><\/li>\n

  4. A.\u00a0L. Stewart, M.\u00a0K. Youngs, and C.\u00a0J. Prend. Fate of heat approaching Antarctica\u2019s largest ice shelves mediated by continental shelf eddies<\/span>. Submitted to<\/em><\/span> Science Advances<\/em><\/span>.<\/p><\/li>\n

  5. H.\u00a0Wei, A.\u00a0L. Stewart, J.\u00a0C. McWilliams, and E.\u00a0Capo. Formation of Abyssal Downwelling-Favorable Prograde Flows via Mesoscale Eddy Potential Vorticity Mixing<\/span>. Submitted to<\/em><\/span> Journal of Physical Oceanography<\/em><\/span>.<\/p><\/li>\n

  6. R.\u00a0Chen, X.\u00a0Su, Q.\u00a0Geng, Z.\u00a0Zhang, A.\u00a0L. Stewart, and G.\u00a0Wang. Satellite altimetry reveals nonlocal energy cascade in the global ocean. Submitted to<\/em><\/span> Science Advances<\/em><\/span>.<\/p><\/li>\n

  7. T.\u00a0Jing, R.\u00a0Chen, A.\u00a0L. Stewart, and C.\u00a0Qiu. Full-Depth Scale-Dependent Eddy Diffusivities in the Kuroshio Extension<\/span>. Submitted to<\/em><\/span> Journal of Physical Oceanography<\/em><\/span>.<\/p><\/li>\n

  8. K.\u00a0Cohanim and A.\u00a0L. Stewart. Symmetric Instability in the Sub-Ice Shelf Pycnocline<\/span>. Submitted to<\/em><\/span> Journal of Physical Oceanography<\/em><\/span>.<\/p><\/li>\n

  9. X.\u00a0Han, Q.\u00a0Wang, A.\u00a0L. Stewart, Z.\u00a0Wang, Q.\u00a0Yang, Q.\u00a0Ni, C.\u00a0Liu, and D.\u00a0Chen. High coastal eddy activity around Antarctica revealed by SWOT<\/span>. Submitted to<\/em><\/span> Nature<\/em><\/span>.<\/p><\/li>\n

  10. W.-I. Lim, H.-S. Park, and A.\u00a0L. Stewart. Future weakening of the Atlantic Meridional Overturning Circulation shaped by reduced Labrador Sea winds and salt transport feedback<\/span>. Submitted to<\/em><\/span> Nature Communications<\/em><\/span>.<\/p><\/li>\n

  11. G.\u00a0Finucane and A.\u00a0L. Stewart. A Theory of Meltwater- Versus Polynya -Dominated Ice Shelf Cavities<\/span>. Submitted to<\/em><\/span> Geophysical Research Letters<\/em><\/span>.<\/p><\/li>\n

  12. C.-Y. Yeh, A.\u00a0L. Stewart, and J.\u00a0C. McWilliams. Regimes of Oceanic Mesoscale Energy Dissipation at Western Boundaries<\/span>. Journal of Physical Oceanography<\/em><\/span>, 56:759\u2013780, 2026.<\/p><\/li>\n

  13. R.\u00a0Moorman, A.\u00a0F. Thompson, M.\u00a0K. Youngs, and A.\u00a0L. Stewart. The Antarctic coastal heat budget is dominated by heat loss to land ice melt<\/span>. Science Advances<\/em><\/span>, 12:eaec7443, 2026.<\/p><\/li>\n

  14. S.\u00a0R. Rintoul, A.\u00a0L. Stewart, G.\u00a0C. Johnson, S.\u00a0Zhou, A.\u00a0Foppert, Q.\u00a0Li, A.\u00a0K. Morrison, A.\u00a0Silvano, K.\u00a0L. Gunn, S.\u00a0Nihashi, and S.\u00a0Aoki. Antarctic Bottom Water in a Changing Climate<\/span>. Nature Reviews Earth & Environment<\/em><\/span>, pages 1\u201317, 2025.<\/p><\/li>\n

  15. X.\u00a0Han, A.\u00a0L. Stewart, Z.\u00a0Wang, C.\u00a0Liu, Q.\u00a0Yang, and D.\u00a0Chen. Tidal enhancement of Antarctic dense shelf water export via suppression of continental slope mixing<\/span>. Journal of Physical Oceanography<\/em><\/span>, 55:2179\u20132195, 2025.<\/p><\/li>\n

  16. C.\u00a0J. Prend, S.\u00a0Swart, A.\u00a0L. Stewart, M.\u00a0D. du\u00a0Pleiss, G.\u00a0E. Manucharyan, and A.\u00a0F. Thompson. Observed regimes of submesoscale dynamics in the Southern Ocean seasonal ice zone<\/span>. Nature Communications<\/em><\/span>, 16:8344, 2025.<\/p><\/li>\n

  17. X.\u00a0Han, A.\u00a0L. Stewart, Z.\u00a0Wang, Q.\u00a0Yang, C.\u00a0Liu, and D.\u00a0Chen. Tidal effects on Antarctic Bottom Water formation in a changing climate<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 130:e2025JC022443, 2025.<\/p><\/li>\n

  18. H.\u00a0Wei, K.\u00a0Srinivasan, A.\u00a0L. Stewart, A.\u00a0Solodoch, G.\u00a0E. Manucharyan, and A.\u00a0McC. Hogg. Full-depth Reconstruction of Long-Term Meridional Overturning Circulation Variability from Satellite-Measurable Quantities via Machine Learning<\/span>. Journal of Advances in Modeling Earth Systems<\/em><\/span>, 17:e2024MS00491, 2025.<\/p><\/li>\n

  19. J.\u00a0Kosty, K.\u00a0X. Zhao, A.\u00a0L. Stewart, D.\u00a0E. McCoy, D.\u00a0Bianchi, G.\u00a0E. Manucharyan, and D.\u00a0Menemenlis. Marine mammal-based observations of subsurface-intensified eddies in the seasonally sea ice-covered Southern Ocean<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 130:e2024JC021781, 2025.<\/p><\/li>\n

  20. S.\u00a0Spungin, Y.\u00a0Si, and A.\u00a0L. Stewart. Observed Seasonality of Mixed-Layer Eddies and Vertical Heat Transport over the Antarctic Continental Shelf<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 130:e2024JC021564, 2025.<\/p><\/li>\n

  21. R.\u00a0Chen, Y.\u00a0Yang, Q.\u00a0Geng, A.\u00a0L. Stewart, G.\u00a0Flierl, and J.\u00a0Wang. A diagnostic framework linking eddy flux ellipse with eddy-mean energy exchange. Ocean-Land-Atmosphere Research<\/em><\/span>, 24:007, 2024.<\/p><\/li>\n

  22. J.\u00a0Jeffree, A.\u00a0McC. Hogg, A.\u00a0K. Morrison, A.\u00a0Solodoch, A.\u00a0L. Stewart, and R.\u00a0McGirr. GRACE satellite observations of Antarctic Bottom Water transport variability<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 129:e2024JC020990, 2024.<\/p><\/li>\n

  23. S.\u00a0Meng, A.\u00a0L. Stewart, and G.\u00a0Manucharyan. Circumpolar transport and overturning strength inferred from satellite observables using Deep Learning in an eddying Southern Ocean channel model<\/span>. Journal of Advances in Modeling Earth Systems<\/em><\/span>, 16:e2024MS004262, 2024.<\/p><\/li>\n

  24. A.\u00a0L. Stewart, Y.\u00a0Wang, A.\u00a0Solodoch, R.\u00a0Chen, and J.\u00a0C. McWilliams. Formation of eastern boundary undercurrents via mesoscale eddy rectification. Journal of Physical Oceanography<\/em><\/span>, 54:1765\u20131785, 2024.<\/p><\/li>\n

  25. J.\u00a0E. Moscoso, D.\u00a0Bianchi, and A.\u00a0L. Stewart. Controls of Cross-Shore Planktonic Ecosystem Structure in an Idealized Eastern Boundary Upwelling System<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 129:e2023JC020458, 2024.<\/p><\/li>\n

  26. G.\u00a0D. Finucane and A.\u00a0L. Stewart. A Predictive Theory for Heat Transport Into Ice Shelf Cavities<\/span>. Geophysical Research Letters<\/em><\/span>, 51:e2024GL108196, 2024.<\/p><\/li>\n

  27. Y.\u00a0Si, A.\u00a0L. Stewart, A.\u00a0Silvano, and A.\u00a0C. Naveira\u00a0Garabato. Antarctic slope undercurrent and onshore heat transport driven by ice shelf melting. Science Advances<\/em><\/span>, 10:eadl0601, 2024.<\/p><\/li>\n

  28. X.\u00a0Han, A.\u00a0L. Stewart, D.\u00a0Chen, M.\u00a0Janout, X.\u00a0Liu, Z.\u00a0Wang, and A.\u00a0L. Gordon. Circum-Antarctic bottom water formation mediated by tides and topographic waves<\/span>. Nature Communications<\/em><\/span>, 15:2049, 2024.<\/p><\/li>\n

  29. H.\u00a0Jeong, S.-S. Lee, H.-S. Park, and A.\u00a0L. Stewart. Future changes in Antarctic coastal polynyas and bottom water formation simulated by a high-resolution coupled model<\/span>. Communications in Earth and Environment<\/em><\/span>, 4:490, 2023.<\/p><\/li>\n

  30. A.\u00a0Silvano, S.\u00a0Purkey, P.\u00a0Castagno, A.\u00a0L. Stewart, S.\u00a0Rintoul, A.\u00a0Foppert, S.\u00a0Aoki, A.\u00a0C. Naveira\u00a0Garabato, C.\u00a0H. Akhoudas, J.-B. Sall\u00e9e, A.\u00a0L. Gordon, E.\u00a0P. Abrahamsen, A.\u00a0J.\u00a0S. Meijers, M.\u00a0P. Meredith, S.\u00a0Zhou, T.\u00a0Tamura, K.\u00a0I. Ohshima, P.\u00a0Falco, G.\u00a0Budillon, T.\u00a0Hattermann, M.\u00a0A. Janout, H.\u00a0H. Hellmer, M.\u00a0M. Bowen, E.\u00a0Darelius, S.\u00a0\u00d8sterhus, K.\u00a0Nicholls, C.\u00a0Stevens, L.\u00a0Cimoli, G.\u00a0D. Williams, A.\u00a0Morrison, and A.\u00a0McC. Hogg. Observing Antarctic Bottom Water in the Southern Ocean<\/span>. Frontiers in Marine Science<\/em><\/span>, 10:1221701, 2023.<\/p><\/li>\n

  31. C.\u00a0R. Schmidgall, Y.\u00a0Si, A.\u00a0L. Stewart, A.\u00a0F. Thompson, and A.\u00a0McC. Hogg. Dynamical Controls on Bottom Water Transport and Transformation across the Antarctic Circumpolar Current<\/span>. Journal of Physical Oceanography<\/em><\/span>, 53:1917\u20131940, 2023.<\/p><\/li>\n

  32. X.\u00a0Han, A.\u00a0L. Stewart, D.\u00a0Chen, X.\u00a0Liu, and T.\u00a0Lian. Controls of topographic Rossby wave properties and downslope transport in dense overflows<\/span>. Journal of Physical Oceanography<\/em><\/span>, 53:1805\u20131820, 2023.<\/p><\/li>\n

  33. Y.\u00a0Si, A.\u00a0L. Stewart, and I.\u00a0Eisenman. Heat transport across the Antarctic Slope Front controlled by cross-slope salinity gradients<\/span>. Science Advances<\/em><\/span>, 9:eadd7049, 2023.<\/p><\/li>\n

  34. A.\u00a0L. Stewart, N.\u00a0K. Neumann, and A.\u00a0Solodoch. Eddy<\/q> saturation of the Antarctic Circumpolar Current by standing waves<\/span>. Journal of Physical Oceanography<\/em><\/span>, 53:1161\u20131181, 2023.<\/p><\/li>\n

  35. A.\u00a0Solodoch, A.\u00a0L. Stewart, A.\u00a0McC. Hogg, and G.\u00a0Manucharyan. Machine Learning-Derived Inference of the Meridional Overturning Circulation from Satellite-Observable Variables in an Ocean State Estimate<\/span>. Journal of Advances in Modeling Earth Systems<\/em><\/span>, 15:e2022MS003370, 2023.<\/p><\/li>\n

  36. A.\u00a0Jagannathan, K.\u00a0Srinivasan, J.\u00a0C. McWilliams, M.\u00a0J. Molemaker, and A.\u00a0L. Stewart. Evolution of bottom boundary layers on three dimensional topography \u2014 Buoyancy adjustment and instabilities<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 128:e2023JC019705, 2023.<\/p><\/li>\n

  37. K.\u00a0X. Zhao, A.\u00a0L. Stewart, J.\u00a0C. McWillliams, I.\u00a0G. Fenty, and E.\u00a0J. Rignot. Standing Eddies in Glacial Fjords and their Role in Fjord Circulation and Melt<\/span>. Journal of Physical Oceanography<\/em><\/span>, 53:821\u2013840, 2023.<\/p><\/li>\n

  38. A.\u00a0Silvano, P.\u00a0Holland, K.\u00a0A. Naughten, O.\u00a0Dragomir, P.\u00a0Dutrieux, A.\u00a0Jenkins, Y.\u00a0Si, A.\u00a0L. Stewart, B.\u00a0Pe\u00f1a-Molino, J.\u00a0Janzing, T.\u00a0S. Dotto, and A.\u00a0C. Naveira\u00a0Garabato. Baroclinic ocean response to climate forcing regulates decadal variability of ice-shelf melting in the Amundsen Sea<\/span>. Geophysical Research Letters<\/em><\/span>, 49:e2022GL100646, 2022.<\/p><\/li>\n

  39. G.\u00a0E. Manucharyan and A.\u00a0L. Stewart. Stirring of Interior Potential Vorticity Gradients as a Formation Mechanism for Large Subsurface-Intensified Eddies in the Beaufort Gyre<\/span>. Journal of Physical Oceanography<\/em><\/span>, 52:3349\u20133370, 2022.<\/p><\/li>\n

  40. H.\u00a0Wei, Y.\u00a0Wang, A.\u00a0L. Stewart, and J.\u00a0Mak. Scalings for eddy buoyancy fluxes across prograde shelf\/slope fronts<\/span>. Journal of Advances in Modeling Earth Systems<\/em><\/span>, 14:e2022MS003229, 2022.<\/p><\/li>\n

  41. X.\u00a0Han, A.\u00a0L. Stewart, D.\u00a0Chen, T.\u00a0Lian, X.\u00a0Liu, and X.\u00a0Xie. Topographic Rossby Wave-modulated oscillations of dense overflows<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 127:e2022JC018702, 2022.<\/p><\/li>\n

  42. K.\u00a0X. Zhao, A.\u00a0L. Stewart, and J.\u00a0C. McWillliams. Linking Overturning, Recirculation, and Melt in Glacial Fjords<\/span>. Geophysical Research Letters<\/em><\/span>, 49:e2021GL097211, 2022.<\/p><\/li>\n

  43. Y.\u00a0Si, A.\u00a0L. Stewart, and I.\u00a0Eisenman. Coupled ocean\/sea ice dynamics of the Antarctic Slope Current driven by topographic eddy suppression and sea ice momentum redistribution<\/span>. Journal of Physical Oceanography<\/em><\/span>, 52:1563\u20131589, 2022.<\/p><\/li>\n

  44. A.\u00a0L. Stewart and J.\u00a0C. McWilliams. Gravity is Vertical in Geophysical Fluid Dynamics<\/span>. Scientific Reports<\/em><\/span>, page 6029, 2022.<\/p><\/li>\n

  45. A.\u00a0Solodoch, A.\u00a0L. Stewart, A.\u00a0McC. Hogg, A.\u00a0K. Morrison, A.\u00a0E. Kiss, A.\u00a0F. Thompson, S.\u00a0G. Purkey, and L.\u00a0Cimoli. How does Antarctic Bottom Water Cross the Southern Ocean?<\/span> Geophysical Research Letters<\/em><\/span>, page e2021GL097211, 2022.<\/p><\/li>\n

  46. J.\u00a0E. Moscoso, D.\u00a0Bianchi, and A.\u00a0L. Stewart. Controls and characteristics of biomass quantization in size-structured planktonic ecosystem models<\/span>. Ecological Modelling<\/em><\/span>, 468:109907, 2022.<\/p><\/li>\n

  47. E.\u00a0A. Wilson, A.\u00a0F. Thompson, A.\u00a0L. Stewart, and S.\u00a0Sun. Bottom-up control of subpolar gyres and the overturning circulation in the Southern Ocean<\/span>. Journal of Physical Oceanography<\/em><\/span>, 52:205\u2013223, 2022.<\/p><\/li>\n

  48. W.-I. Lim, H.-S. Park, A.\u00a0L. Stewart, and K.-H. Seo. Suppression of Arctic sea ice growth in the Eurasian-Pacific Seas by winter clouds and snowfall<\/span>. Journal of Climate<\/em><\/span>, 35:669\u2013686, 2022.<\/p><\/li>\n

  49. A.\u00a0L. Stewart. Mesoscale, tidal and seasonal\/interannual drivers of the Weddell Sea overturning circulation<\/span>. Journal of Physical Oceanography<\/em><\/span>, 51:3695\u20133722, 2021.<\/p><\/li>\n

  50. A.\u00a0L. Stewart, X.\u00a0Chi, A.\u00a0Solodoch, and A.\u00a0McC. Hogg. High-frequency fluctuations in Antarctic Bottom Water transport driven by Southern Ocean winds<\/span>. Geophysical Research Letters<\/em><\/span>, 8:e2021GL094569, 2021.<\/p><\/li>\n

  51. K.\u00a0Cohanim, K.\u00a0X. Zhao, and A.\u00a0L. Stewart. Dynamics of Eddies Generated by Sea Ice Leads<\/span>. Journal of Physical Oceanography<\/em><\/span>, 51:3071\u20133092, 2021.<\/p><\/li>\n

  52. Y.\u00a0Bai, Y.\u00a0Wang, and A.\u00a0L. Stewart. Does Topographic Form Stress Impede Prograde Ocean Flows?<\/span> Journal of Physical Oceanography<\/em><\/span>, 51:2617\u20132638, 2021.<\/p><\/li>\n

  53. A.\u00a0Jagannathan, K.\u00a0Srinivasan, J.\u00a0C. McWilliams, M.\u00a0J. Molemaker, and A.\u00a0L. Stewart. Boundary layer-mediated vorticity generation in currents over sloping bathymetry<\/span>. Journal of Physical Oceanography<\/em><\/span>, 51:1757\u20131778, 2021.<\/p><\/li>\n

  54. A.\u00a0L. Stewart, J.\u00a0C. McWilliams, and A.\u00a0Solodoch. On the role of bottom pressure torques in wind-driven gyres<\/span>. Journal of Physical Oceanography<\/em><\/span>, 51:1441\u20131464, 2021.<\/p><\/li>\n

  55. K.\u00a0X. Zhao, A.\u00a0L. Stewart, and J.\u00a0C. McWilliams. Geometric Constraints on Glacial Fjord\u2013Shelf Exchange<\/span>. Journal of Physical Oceanography<\/em><\/span>, 51:207\u2013228, 2021.<\/p><\/li>\n

  56. J.\u00a0E. Moscoso, A.\u00a0L. Stewart, D.\u00a0Bianchi, and J.\u00a0C. McWilliams. The Meridionally Averaged Model of Eastern Boundary Upwelling Systems (MAMEBUSv1.0)<\/span>. Geoscientific Model Development<\/em><\/span>, 14:763\u2013794, 2021.<\/p><\/li>\n

  57. A.\u00a0Solodoch, A.\u00a0L. Stewart, and J.\u00a0C. McWilliams. Formation of anticyclones above topographic depressions<\/span>. Journal of Physical Oceanography<\/em><\/span>, 51:207\u2013228, 2021.<\/p><\/li>\n

  58. D.\u00a0E. McCoy, D.\u00a0Bianchi, and A.\u00a0L. Stewart. Global Observations of Submesoscale Coherent Vortices in the Ocean<\/span>. Progress in Oceanography<\/em><\/span>, 189:102452, 2020.<\/p><\/li>\n

  59. A.\u00a0Solodoch, J.\u00a0C. McWilliams, and A.\u00a0L. Stewart. Why Does the Deep Western Boundary Current Leak<\/q> Around Flemish Cap?<\/span> Journal of Physical Oceanography<\/em><\/span>, 50:1989\u20132016, 2020.<\/p><\/li>\n

  60. J.\u00a0E. Hazel and A.\u00a0L. Stewart. Bi-stability of the Filchner-Ronne Ice Shelf Cavity Circulation and Basal Melt<\/span>. Journal of Geophysical Research: Oceans<\/em><\/span>, 125:e2019JC015848, 2020.<\/p><\/li>\n

  61. S.\u00a0Sun, I.\u00a0Eisenman, L.\u00a0Zanna, and A.\u00a0L. Stewart. Surface constraints on the depth of the Atlantic Meridional Overturning Circulation: Southern Ocean vs North Atlantic<\/span>. Journal of Climate<\/em><\/span>, 33:3125\u20133149, 2020.<\/p><\/li>\n

  62. Y.\u00a0Wang and A.\u00a0L. Stewart. Scalings for eddy buoyancy transfer across continental slopes under retrograde winds<\/span>. Ocean Modelling<\/em><\/span>, 147:101579, 2020.<\/p><\/li>\n

  63. H.-S. Park, S.-J. Kim, A.\u00a0L. Stewart, S.-W. Son, and K.-H.. Seo. Mid-Holocene Northern Hemisphere warming driven by Arctic amplification and sea ice loss<\/span>. Science Advances<\/em><\/span>, 5(12), 2019.<\/p><\/li>\n

  64. A.\u00a0L. Stewart. Approximating isoneutral ocean transport via the Temporal Residual Mean<\/span>. Fluids<\/em><\/span>, 4:179, 2019.<\/p><\/li>\n

  65. A.\u00a0L. Stewart, A.\u00a0Klocker, and D.\u00a0Menemenlis. Acceleration and overturning of the Antarctic Slope Current by winds, eddies, and tides<\/span>. Journal of Physical Oceanography<\/em><\/span>, 43:2043\u20132074, 2019.<\/p><\/li>\n

  66. J.\u00a0E. Hazel and A.\u00a0L. Stewart. Multi-Decadal Trends in Easterly Wind Stress around the Antarctic Coast<\/span>. Journal of Climate<\/em><\/span>, 32:1895\u20131918, 2019.<\/p><\/li>\n

  67. K.\u00a0X. Zhao, A.\u00a0L. Stewart, and J.\u00a0C. McWilliams. Sill-Influenced Exchange Flows in Ice Shelf Cavities<\/span>. Journal of Physical Oceanography<\/em><\/span>, 49:163\u2013191, 2019.<\/p><\/li>\n

  68. A.\u00a0F. Thompson, A.\u00a0L. Stewart, P.\u00a0Spence, and K.\u00a0J. Heywood. The Antarctic Slope Front in a Changing Climate<\/span>. Reviews of Geophysics<\/em><\/span>, 56:741\u2013770, 2018.<\/p><\/li>\n

  69. H.-S. Park, S.-J. Kim, K.-H. Seo, A.\u00a0L. Stewart, and S.-Y. Kim. The impact of Arctic sea ice loss on mid-Holocene climate<\/span>. Nature Communications<\/em><\/span>, 9:4571, 2018.<\/p><\/li>\n

  70. S.\u00a0Sun, I.\u00a0Eisenman, and A.\u00a0L. Stewart. Does Southern Ocean surface forcing shape the global ocean overturning circulation?<\/span> Geophysical Research Letters<\/em><\/span>, 45:2413\u20132423, 2018.<\/p><\/li>\n

  71. A.\u00a0L. Stewart, A.\u00a0Klocker, and D.\u00a0Menemenlis. Circum-Antarctic shoreward heat transport derived from an eddy- and tide-resolving simulation<\/span>. Geophysical Research Letters<\/em><\/span>, 45:834\u2013845, 2018.<\/p><\/li>\n

  72. H.-S. Park, A.\u00a0L. Stewart, and J.-H. Son. Dynamic and thermodynamic impacts of the winter Arctic Oscillation on summer sea ice extent<\/span>. Journal of Climate<\/em><\/span>, 31:1483\u20131497, 2018.<\/p><\/li>\n

  73. Y.\u00a0Wang and A.\u00a0L. Stewart. Eddy dynamics over continental slopes under retrograde winds: Insights from a model inter-comparison. Ocean Modelling<\/em><\/span>, 121:1\u201318, 2018.<\/p><\/li>\n

  74. A.\u00a0L. Stewart and A.\u00a0McC. Hogg. Reshaping the Antarctic Circumpolar Current via Antarctic Bottom Water export<\/span>. Journal of Physical Oceanography<\/em><\/span>, 47:2577\u20132601, 2017.<\/p><\/li>\n

  75. A.\u00a0L. Stewart and A.\u00a0F. Thompson. Eddy generation and jet formation via dense water outflows across the Antarctic continental slope<\/span>. Journal of Physical Oceanography<\/em><\/span>, 46:3729\u20133750, 2016.<\/p><\/li>\n

  76. A.\u00a0F. Thompson, A.\u00a0L. Stewart, and T.\u00a0Bischoff. A multi-basin residual-mean model for the global overturning circulation<\/span>. Journal of Physical Oceanography<\/em><\/span>, 46:2583\u20132604, 2016.<\/p><\/li>\n

  77. S.\u00a0Sun, I.\u00a0Eisenman, and A.\u00a0L. Stewart. Southern Ocean surface buoyancy forcing controls glacial-interglacial changes in the global deep ocean stratification<\/span>. Geophysical Research Letters<\/em><\/span>, 43:8124\u20138132, 2016.<\/p><\/li>\n

  78. A.\u00a0Solodoch, A.\u00a0L. Stewart, and J.\u00a0C. McWilliams. Baroclinic instability of axially-symmetric flow over sloping bathymetry<\/span>. Journal of Fluid Mechanics<\/em><\/span>, 799:265\u2013296, 2016.<\/p><\/li>\n

  79. Z.\u00a0Su, A.\u00a0Ingersoll, A.\u00a0L. Stewart, and A.\u00a0F. Thompson. Ocean Convective Available Potential Energy. Part I: Concept and Calculation<\/span>. Journal of Physical Oceanography<\/em><\/span>, 46:1081\u20131096, 2016.<\/p><\/li>\n

  80. Z.\u00a0Su, A.\u00a0Ingersoll, A.\u00a0L. Stewart, and A.\u00a0F. Thompson. Ocean Convective Available Potential Energy. Part II: Energetics of Thermobaric Convection<\/span>. Journal of Physical Oceanography<\/em><\/span>, 46:1097\u20131115, 2016.<\/p><\/li>\n

  81. A.\u00a0L. Stewart and P.\u00a0J. Dellar. An energy and potential enstrophy conserving numerical scheme for the multi-layer shallow water equations with complete Coriolis force<\/span>. Journal of Computational Physics<\/em><\/span>, 313:99\u2013120, 2016.<\/p><\/li>\n

  82. H.-S. Park and A.\u00a0L. Stewart. An analytical model for wind-driven Arctic summer sea ice drift<\/span>. The Cryosphere<\/em><\/span>, 10:227\u2013244, 2016.<\/p><\/li>\n

  83. A.\u00a0Burke, A.\u00a0L. Stewart, J.\u00a0F. Adkins, R.\u00a0Ferrari, M.\u00a0F. Jansen, and A.\u00a0F. Thompson. The glacial mid-depth radiocarbon bulge and its implications for the overturning circulation. Paleoceanography<\/em><\/span>, 30:1021\u20131039, 2015.<\/p><\/li>\n

  84. A.\u00a0L. Stewart and A.\u00a0F. Thompson. The Neutral Density Temporal Residual Mean overturning circulation<\/span>. Ocean Modelling<\/em><\/span>, 90:44\u201356, 2015.<\/p><\/li>\n

  85. V.\u00a0C. Tsai, A.\u00a0L. Stewart, and A.\u00a0F. Thompson. Marine ice-sheet profiles and stability under Coulomb basal conditions<\/span>. Journal of Glaciology<\/em><\/span>, 61(226):205, 2015.<\/p><\/li>\n

  86. A.\u00a0L. Stewart and A.\u00a0F. Thompson. Eddy-mediated transport of warm Circumpolar Deep Water across the Antarctic Shelf Break<\/span>. Geophysical Research Letters<\/em><\/span>, 42:432\u2013440, 2015.<\/p><\/li>\n

  87. A.\u00a0L. Stewart, P.\u00a0J. Dellar, and E.\u00a0R. Johnson. Large-amplitude coastal shelf waves. In T.\u00a0von Larcher and P.\u00a0D. Williams, editors, Modeling Atmospheric and Oceanic Flows<\/em><\/span>, pages 229\u2013253. Wiley, Hoboken, NJ, 2014.<\/p><\/li>\n

  88. R.\u00a0Ferrari, M.\u00a0F. Jansen, J.\u00a0F. Adkins, A.\u00a0Burke, A.\u00a0L. Stewart, and A.\u00a0F. Thompson. Antarctic sea ice control on ocean circulation in present and glacial climates<\/span>. Proceedings of the National Academy of Sciences<\/em><\/span>, 111(24):8753\u20138758, 2014.<\/p><\/li>\n

  89. A.\u00a0F. Thompson, K.\u00a0J. Heywood, S.\u00a0Schmidtko, and A.\u00a0L. Stewart. Eddy transport as a key component of the Antarctic overturning circulation<\/span>. Nature Geoscience<\/em><\/span>, 7(12):879\u2013884, 2014.<\/p><\/li>\n

  90. A.\u00a0L. Stewart, R.\u00a0Ferrari, and A.\u00a0F. Thompson. On the importance of surface forcing in conceptual models of the deep ocean. Journal of Physical Oceanography<\/em><\/span>, 44(3):891\u2013899, 2014.<\/p><\/li>\n

  91. Z.\u00a0Su, A.\u00a0L. Stewart, and A.\u00a0F. Thompson. An idealized model of Weddell Gyre export variability<\/span>. Journal of Physical Oceanography<\/em><\/span>, 44(6):1671\u20131688, 2014.<\/p><\/li>\n

  92. A.\u00a0L. Stewart and A.\u00a0F. Thompson. Connecting Antarctic Cross-Slope Exchange with Southern Ocean Overturning<\/span>. Journal of Physical Oceanography<\/em><\/span>, 43:1453\u20131471, 2013.<\/p><\/li>\n

  93. A.\u00a0L. Stewart and P.\u00a0J. Dellar. Multilayer shallow water equations with complete Coriolis force. Part 3. Hyperbolicity and stability under shear<\/span>. Journal of Fluid Mechanics<\/em><\/span>, 723:289\u2013317, 2013.<\/p><\/li>\n

  94. A.\u00a0L. Stewart and A.\u00a0F. Thompson. Sensitivity of the ocean\u2019s deep overturning circulation to easterly Antarctic winds<\/span>. Geophysical Research Letters<\/em><\/span>, 39(18):L18604, 2012.<\/p><\/li>\n

  95. A.\u00a0L. Stewart and P.\u00a0J. Dellar. Cross-equatorial channel flow with zero potential vorticity under the complete Coriolis force<\/span>. IMA Journal of Applied Mathematics<\/em><\/span>, 77:626\u2013651, 2012.<\/p><\/li>\n

  96. A.\u00a0L. Stewart and P.J. Dellar. Multilayer shallow water equations with complete Coriolis force. Part 2. Linear plane waves<\/span>. Journal of Fluid Mechanics<\/em><\/span>, 690:16\u201350, 2012.<\/p><\/li>\n

  97. A.\u00a0L. Stewart and P.\u00a0J. Dellar. Cross-equatorial flow through an abyssal channel under the complete Coriolis force: two dimensional solutions<\/span>. Ocean Modelling<\/em><\/span>, 40:87\u2013104, 2011.<\/p><\/li>\n

  98. A.\u00a0L. Stewart and P.J. Dellar. The role of the complete Coriolis force in cross-equatorial flow of abyssal ocean currents<\/span>. Ocean Modelling<\/em><\/span>, 38:187\u2013202, 2011.<\/p><\/li>\n

  99. A.\u00a0L. Stewart, P.\u00a0J. Dellar, and E.\u00a0R. Johnson. Numerical simulation of wave propagation along a discontinuity in depth in a rotating annulus<\/span>. Computers & Fluids<\/em><\/span>, 46:442\u2013447, 2011.<\/p><\/li>\n

  100. A.\u00a0L. Stewart and P.\u00a0J. Dellar. Multilayer shallow water equations with complete Coriolis force. Part I. Derivation on a non-traditional beta-plane<\/span>. Journal of Fluid Mechanics<\/em><\/span>, 651:387\u2013413, 2010.<\/p><\/li>\n<\/ol>\n

    Other Publications<\/h2>\n
    \n
      \n

    1. E.\u00a0K.\u00a0M. Chang, C.\u00a0L.\u00a0P. Wolfe, A.\u00a0L. Stewart, and J.\u00a0C. McWilliams. Comments on Horizontal gravity disturbance vector in atmospheric dynamics<\/q> by Peter C. Chu<\/span>. Dynamics of Atmospheres and Oceans<\/em><\/span>, 103:101382, 2023.<\/p><\/li>\n

    2. A.\u00a0L. Stewart. Physical oceanography: Warming spins up the Southern Ocean<\/span>. Nature Climate Change<\/em><\/span>, 11:1022\u20131024, 2021.<\/p><\/li>\n

    3. A.\u00a0L. Stewart. Oceanography: Mixed up at the sea floor. Nature<\/em><\/span>, 551(7679):178\u2013179, 2017.<\/p><\/li>\n

    4. A.\u00a0L. Stewart. The role of the complete Coriolis force in cross-equatorial transport of abyssal ocean currents<\/span><\/em><\/span>. PhD thesis, University of Oxford, 2011.<\/p><\/li>\n

    5. A.\u00a0L. Stewart and P.\u00a0J. Dellar. Two-layer shallow water equations with complete Coriolis force and topography<\/span>. Progress in Industrial Mathematics at ECMI 2008<\/em><\/span>, pages 1033\u20131038, 2010.<\/p><\/li>\n

    6. A.\u00a0L. Stewart. Nonlinear shelf waves in a rotating annulus<\/span>. Technical Report of the 2009 Geophysical Fluid Dynamics Program at Woods Hole Oceanographic Institution<\/em><\/span>, 2010.<\/p><\/li>\n<\/ol>\n

      Awards<\/h2>\n
      \n
        \n

      • Lawrence Harding Endowed Chair, 2024\u20132027<\/p><\/li>\n

      • Fofonoff Early Career Award, American Meteorological Society, 2022<\/p><\/li>\n

      • NSF Faculty Career Development (CAREER) Award, 2018\u20132023<\/p><\/li>\n

      • UCLA Atmospheric and Oceanic Sciences Chi Epsilon Pi Gaston<\/q> Award, November 2017<\/p><\/li>\n

      • University of California Hellman Fellows Award, 2016\u20132017<\/p><\/li>\n

      • Editor\u2019s Award, Journal of Atmospheric and Oceanic Technology<\/em>, American Meteorological Society, 2016<\/p><\/li>\n

      • SCAR Travel Grant Award for the XXXII SCAR Open Science Conference 2012<\/p><\/li>\n

      • Finalist, 1st<\/sup> biennial Lighthill\u2013Thwaites prize at the British Applied Mathematics Colloquium 2011<\/p><\/li>\n

      • European Space Agency sponsorship for the European Geosciences Union General Assembly 2011<\/p><\/li>\n

      • Senior Scholarship, Corpus Christi College, Oxford, October 2010 \u2013 September 2011<\/p><\/li>\n

      • Garside Senior Scholarship, Corpus Christi College, Oxford, October 2008 \u2013 September 2010<\/p><\/li>\n

      • Mathematical, Physical and Life Sciences Division Prize for a Presentation at the Graduate Student Symposium, October 2009<\/p><\/li>\n

      • The Institute of Marine Engineering, Science and Technology Prize for Best Student Presentation at Challenger Society Ocean Modelling Group Meeting, September 2009<\/p><\/li>\n

      • Geophysical Fluid Dynamics Fellowship at Woods Hole Oceanographic Institution, June \u2013 August 2009<\/p><\/li>\n

      • The Quarterly Journal of Mechanics and Applied Mathematics Prize for Best Student Presentation at the British Applied Mathematics Colloquium, April 2009<\/p><\/li>\n

      • Marie Curie Scholarship for the 7th<\/sup> EUROMECH Fluid Mechanics Conference, September 2008<\/p><\/li>\n

      • Institute of Mathematics and its Applications prize for the Best Undergraduate Mathematics Project in Scotland, June 2007<\/p><\/li>\n

      • Institute of Mathematics and its Applications prize for Outstanding Performance in MMath Mathematics, June 2007<\/p><\/li>\n<\/ul>\n

        Research Support<\/h2>\n
        \n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
        Dec 2024 \u2013 Nov 2027<\/td>\nParameterizing Ice Shelf Cavity Processes and Basal Melt in NASA Earth System Models<\/q><\/em><\/span>, NASA NNH23ZDA001N-FINESST (FINESST Earth Sciences Program) $150,000, F.I.\u00a0Garrett Finucane, P.I.\u00a0Andrew Stewart.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Aug 2023\u2013 Jul 2026<\/td>\nEstimating Spatiotemporal Meridional Overturning Circulation Variability from Satellite Observations using Machine Learning<\/q><\/em><\/span>, NASA ROSES (Physical Oceanography Program) $570,588, P.I.\u00a0Andrew Stewart, Co-PIs.\u00a0Georgy Manucharyan and Andrew Hogg.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Sep 2022 \u2013 Aug 2026<\/td>\nCollaborative Research: Characteristics and origins of eddies beneath Antarctic sea ice<\/q><\/em><\/span>, NSF ANT-2220968 (Antarctic Ocean and Atmospheric Sciences) $432,824, P.I.s\u00a0Andrew Stewart, Daniele Bianchi and Georgy Manucharyan.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Sep 2020 \u2013 Aug 2024<\/td>\nCollaborative Research: The Antarctic Circumpolar Current: A Conduit or Blender of Antarctic Bottom Waters?<\/q><\/em><\/span>, NSF ANT-2023244 (Antarctic Ocean and Atmospheric Sciences) $344,969, P.I.s\u00a0Andrew Stewart, Andrew Thompson and Sarah Purkey, Co-I.\u00a0Andrew Hogg.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Aug 2019 \u2013 Jul 2022<\/td>\nRemotely Sensing Overturning Circulation Variability in the Southern Ocean<\/q><\/em><\/span>, NASA ROSES 80NSSC19K1192 (Physical Oceanography Program) $333,751, P.I.\u00a0Andrew Stewart, Co-I.\u00a0Andrew Hogg.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Jul 2018 \u2013 Jun 2023<\/td>\nCAREER: Circumpolar Variability and Exchanges Across the Antarctic Slope Front<\/q><\/em><\/span>, NSF OCE-1751386 (Physical Oceanography Program) $693,995 (of $945,908 total), P.I.\u00a0Andrew Stewart.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Aug 2021 \u2013 Jul 2022<\/td>\nMachine Learning of the Ocean Overturning Circulation<\/q><\/em><\/span>, IDRE Postdoctoral Fellowship, $5,000, Postdoctoral Investigator Aviv Solodoch, P.I.\u00a0Andrew Stewart.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Sep 2020 \u2013 Aug 2022<\/td>\nImproving Glacial Melt Rate Estimates Using ECCO and NASA OMG<\/q><\/em><\/span>, NASA 19-EARTH20-0153 (FINESST Earth Sciences Program) $90,000, F.I. Ken Zhao, P.I.\u00a0Andrew Stewart, Co-I James McWilliams.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Sep 2016 \u2013 Aug 2020<\/td>\nEddy\/Tidal Water Mass Transformation and Transport in the Weddell Sea<\/q><\/em><\/span>, NSF ANT-1543388 (Antarctic Ocean and Atmospheric Sciences) $428,209, P.I.\u00a0Andrew Stewart.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Sep 2015 \u2013 Aug 2019<\/td>\nParametrizing Eddy Transfer Over Continental Slopes<\/q><\/em><\/span>, NSF OCE-1538702 (Physical Oceanography Program) $472,412, P.I.\u00a0Andrew Stewart.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Jul 2016 \u2013 Jul 2017<\/td>\nMelting the Giant: Modeling Oceanic Heating of the Antarctic Ice Sheet<\/q><\/em><\/span>, UC Hellman Fellowship $28,812, P.I.\u00a0Andrew Stewart.<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

        Computational Support<\/h2>\n
        \n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
        Oct 2025 \u2013 Oct 2026<\/td>\nEES240122: Simulating Ocean Abyssal Upwelling over Sloping Seafloors<\/q><\/em><\/span>, ACCESS-CI Accelerate ACCESS Research Allocation, 3,000,000 ACCESS credits, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Mar 2025 \u2013 Mar 2026<\/td>\nEES230085: Simulating Circumpolar Variability and Exchanges Across the Antarctic Slope Front<\/q><\/em><\/span>, ACCESS-CI Accelerate ACCESS Research Allocation, 3,000,000 ACCESS credits, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Oct 2024 \u2013 Oct 2025<\/td>\nEES240122: Simulating Ocean Abyssal Upwelling over Sloping Seafloors<\/q><\/em><\/span>, ACCESS-CI Discover ACCESS Research Allocation, 1,500,000 ACCESS credits, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Oct 2023 \u2013 Mar 2025<\/td>\nOCE160020: Simulating Circumpolar Variability and Exchanges Across the Antarctic Slope Front<\/q><\/em><\/span>, ACCESS-CI Accelerate ACCESS Research Allocation, 3,000,000 ACCESS credits, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Oct 2021 \u2013 Mar 2023<\/td>\nSimulating Circumpolar Variability and Exchanges Across the Antarctic Slope Front<\/q><\/em><\/span>, XSEDE Research Allocation Renewal, $51,324.80 in compute resources, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Oct 2020 \u2013 Sep 2021<\/td>\nSimulating Circumpolar Variability and Exchanges Across the Antarctic Slope Front<\/q><\/em><\/span>, XSEDE Research Allocation Renewal, $10,384.00 in compute resources, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Apr 2019 \u2013 Sep 2020<\/td>\nSimulating eddy heat transport in the high-latitude oceans<\/q><\/em><\/span>, XSEDE Research Allocation Renewal, $44,787.23 in compute resources, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Apr 2018 \u2013 Mar 2018<\/td>\nSimulating ocean eddy transfer across continental slopes and in the Weddell Sea<\/q><\/em><\/span>, XSEDE Research Allocation Renewal, $81,899.31 in compute resources, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Jan 2017 \u2013 Dec 2017<\/td>\nSimulating ocean eddy transfer across continental slopes and in the Weddell Sea<\/q><\/em><\/span>, XSEDE Research Allocation, $59,526.98 in compute resources, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Jul 2016 \u2013 Jun 2017<\/td>\nMelting the Giant: Modeling Oceanic Heating of the Antarctic Ice Sheet<\/q><\/em><\/span>, San Diego Supercomputing Center HPC@UC Award, 500,000 SUs, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Sep 2014 \u2013 Mar 2016<\/td>\nEddy mixing and transport across continental slopes<\/q><\/em><\/span>, XSEDE TG-OCE140020 (Startup Allocation), 176,500 SUs, P.I.\u00a0Andrew Stewart<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

        Education Support<\/h2>\n
        \n\n\n\n\n\n\n\n\n\n\n
        Jul 2018 \u2013 Jul 2023<\/td>\nCAREER: Circumpolar Variability and Exchanges Across the Antarctic Slope Front<\/q><\/em><\/span>, NSF OCE-1751386 (Physical Oceanography Program) $251,913 (of $945,908 total), P.I.\u00a0Andrew Stewart.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Jul 2021 \u2013 Jun 2022<\/td>\nAsynchronous Rotating Tank Experiment Videos to Enhance Undergraduate Comprehension in Atmospheric and Oceanic Fluids<\/q><\/em><\/span>, IIP #21-08 (UCLA Center for Advancement of Teaching) $9,849.36, P.I.\u00a0Andrew Stewart, Co-P.I.s Jordyn Moscoso and Gang Chen<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Jul 2019 \u2013 Jun 2020<\/td>\nIntegrating Research Cruises into Oceanographic Undergraduate Education<\/q><\/em><\/span>, IIP #19-03 (UCLA Center for Advancement of Teaching) $9,870.50, P.I.\u00a0Daniele Bianchi, Co-P.Is. Andrew Stewart and Jeroen Molemaker<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Jul 2018 \u2013 Jun 2019<\/td>\nIncreasing Undergraduate Comprehension of Atmospheric and Ocean Fluids via Rotating Tank Experiments<\/q><\/em><\/span>, IIP #18-09 (UCLA Office of Instructional Development) $9,290, P.I.\u00a0Andrew Stewart, Co-P.I. Gang Chen.<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

        Teaching<\/h2>\n
        \n

        Numbers in parentheses indicate average student evaluations of instructor\/course, on a scale of 1 to 9. I was granted a release from teaching in Fall 2014, Fall 2015, Fall 2016, Fall 2017, and Winter 2022. I was on sabbatical during Winter 2021 and Winter 2024.<\/span><\/p>\n\n\n\n\n\n\n\n\n\n\n\n\n\n
        Physical Oceanography (Undergraduate, upper-division)<\/td>\nWinter 2015 (7.86\/6.88), Winter 2016 (7.49\/6.65), Winter 2017 (8.01\/7.16), Winter 2018 (8.39\/7.84), Fall 2018 (8.20\/7.85), Fall 2019 (8.49\/7.82), Fall 2020 (8.24\/7.81), Fall 2021 (8.20\/8.16), Fall 2022 (8.13\/7.54), Fall 2023 (8.14\/7.16), Fall 2024 (8.39\/8.05)<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        California\u2019s Ocean (Undergraduate, upper-division)<\/td>\nSpring 2015 (8.67\/8.56), Spring 2016 (8.36\/8.07), Spring 2017 (8.25\/7.33), Spring 2018 (8.75\/8.33), Spring 2019 (8.89\/8.78), Spring 2020 (8.7\/8.33), Spring 2021 (7.75\/6.00), Spring 2022 (9.00\/9.00), Spring 2023 (8.64\/8.30), Spring 2024 (9.00\/9.00), Spring 2025 (8.50\/8.10)<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Geophysical Fluid Dynamics (Advanced Graduate)<\/td>\nSpring 2025 (8.50\/7.50)<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Ocean Circulation (Advanced Graduate)<\/td>\nSpring 2019 (9.00\/9.00), Spring 2020 (9.00\/9.00), Spring 2023<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Oceanography and Climate (Graduate Seminar) Topic: Dynamics of the ocean\u2019s bottom boundary layer<\/em><\/td>\nWinter 2016 (N\/A)<\/td>\n<\/tr>\n
        <\/td>\n<\/td>\n<\/tr>\n
        Ocean Dynamics (Graduate Seminar)<\/td>\nWinter 2018, Spring 2018, Fall 2018, Winter 2019, Spring 2019, Fall 2019, Winter 2020, Spring 2020, Fall 2020, Spring 2021, Fall 2021, Winter 2022, Spring 2022, Fall 2022, Winter 2023, Spring 2023, Fall 2023, Winter 2024, Spring 2024, Fall 2024, Winter 2025, Spring 2025 (N\/A)<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

        Current Research Group Members<\/h2>\n
        \n\n\n\n\n\n\n\n\n\n\n\n\n
        Huaiyu Wei<\/td>\nPostdoctoral researcher, Feb 2024\u2013Present<\/td>\n<\/tr>\n
        Kaylie Cohanim<\/td>\nUndergraduate researcher, Apr 2018\u2013Dec 2019<\/td>\n<\/tr>\n
        <\/td>\nResearch assistant, Jan 2020\u2013Jul 2020<\/td>\n<\/tr>\n
        <\/td>\nPhD student, Jan 2023\u2013Present<\/td>\n<\/tr>\n
        Garrett Finucane<\/td>\nPhD student, Sep 2021\u2013Present<\/td>\n<\/tr>\n
        Sunny Yeh<\/td>\nPhD student, Sep 2021\u2013Present<\/td>\n<\/tr>\n
        Selena Yu<\/td>\nUndergraduate researcher, Jan 2025\u2013Present<\/td>\n<\/tr>\n
        Annika Renganathan<\/td>\nUndergraduate researcher, Jan 2025\u2013Present<\/td>\n<\/tr>\n
        Aisha Mardini<\/td>\nUndergraduate researcher, Apr 2025\u2013Present<\/td>\n<\/tr>\n
        Reid Mendoza<\/td>\nUndergraduate researcher, Jan 2026\u2013Present<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

        Former Research Group Members<\/h2>\n
        \n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
        Ruibin Xia<\/td>\nVisiting researcher, Sep 2019 \u2013 Sep 2020<\/td>\n<\/tr>\n
        Madeleine Youngs<\/td>\nPostdoctoral researcher, Jan 2023\u2013Dec 2024<\/td>\n<\/tr>\n
        Aviv Solodoch (PhD 2020)<\/td>\nPhD student, Sep 2014\u2013Jul 2020. Thesis: Topographic effects on mesoscale ocean circulation<\/q><\/td>\n<\/tr>\n
        <\/td>\nPostdoctoral researcher, Aug 2020\u2013Jun 2023<\/td>\n<\/tr>\n
        Yan Wang<\/td>\nPostdoctoral researcher, Jan 2016 \u2013 Aug 2018<\/td>\n<\/tr>\n
        Yidongfang Si (PhD 2023)<\/td>\nPhD student, Sep 2018 \u2013 Jun 2023. Thesis: Ice-Ocean Interactions in the Antarctic Slope Current<\/q><\/td>\n<\/tr>\n
        Jordyn Moscoso (PhD 2022)<\/td>\nPhD student, Sep 2016\u2013Jun 2016. Thesis: Controls on planktonic ecosystem structure in Eastern Boundary Upwelling Systems: a modeling perspective<\/q><\/td>\n<\/tr>\n
        Ken Zhao (PhD 2021)<\/td>\nPhD student, Apr 2016\u2013Dec 2021. Thesis: Dynamics of Ocean Circulation in Glacial Fjords and Ice-Shelf Cavities<\/q><\/td>\n<\/tr>\n
        Julia Hazel (PhD 2019)<\/td>\nPhD student, Apr 2015\u2013Jun 2019. Thesis: Exploring the wind-driven near-Antarctic circulation<\/q><\/td>\n<\/tr>\n
        Alex Akin<\/td>\nUndergraduate researcher, Apr 2024\u2013June 2025<\/td>\n<\/tr>\n
        Mia Thorp<\/td>\nUndergraduate researcher, Jan 2024\u2013Dec 2024<\/td>\n<\/tr>\n
        Wyatt Cottriel<\/td>\nUndergraduate researcher, Jan 2023\u2013June 2024<\/td>\n<\/tr>\n
        Eliza Lerman<\/td>\nUndergraduate researcher, Jan 2024\u2013June 2024<\/td>\n<\/tr>\n
        Emily Murrell<\/td>\nUndergraduate researcher, Jan 2023\u2013June 2024<\/td>\n<\/tr>\n
        Sophia Spungin<\/td>\nUndergraduate researcher, Jan 2022\u2013Dec 2024<\/td>\n<\/tr>\n
        Jennifer Kosty<\/td>\nUndergraduate researcher, Oct 2020\u2013Aug 2023<\/td>\n<\/tr>\n
        Jackson Wilke<\/td>\nUndergraduate researcher, Apr 2023\u2013Aug 2023<\/td>\n<\/tr>\n
        Pamela Doran<\/td>\nUndergraduate researcher, Oct 2022\u2013Dec 2022<\/td>\n<\/tr>\n
        Carlyn Schmidgall<\/td>\nUndergraduate researcher, Jan 2019\u2013Jul 2020<\/td>\n<\/tr>\n
        <\/td>\nResearch assistant, Aug 2020\u2013May 2022<\/td>\n<\/tr>\n
        Nicole Neumann<\/td>\nRemote undergraduate researcher, Dec 2020\u2013May 2022<\/td>\n<\/tr>\n
        Xiaoyang Chi<\/td>\nUndergraduate researcher, Apr 2020\u2013Jun 2021<\/td>\n<\/tr>\n
        Yue (Luna) Bai<\/td>\nUndergraduate researcher, Apr 2017\u2013Aug 2020<\/td>\n<\/tr>\n
        Yang (Kitty) Wang<\/td>\nUndergraduate researcher, Sep 2018\u2013Jun 2019<\/td>\n<\/tr>\n
        Tanya Arcienega<\/td>\nUndergraduate researcher, Apr 2018\u2013March 2019<\/td>\n<\/tr>\n
        Wenjia (Josslyn) Cai<\/td>\nUndergraduate researcher, Jan 2017\u2013Mar 2018<\/td>\n<\/tr>\n
        Truc Pham<\/td>\nUndergraduate researcher, Apr 2018\u2013Nov 2018<\/td>\n<\/tr>\n
        Zhao Hua Xu<\/td>\nUndergraduate research student, Aug 2015\u2013Jun 2016<\/td>\n<\/tr>\n
        Shuai Meng<\/td>\nRemote graduate researcher, February 2021\u2013June 2022<\/td>\n<\/tr>\n
        Mathieu Morvan<\/td>\nVisiting graduate researcher, May 2016\u2013Aug 2016<\/td>\n<\/tr>\n
        Victor Ciaramitaro<\/td>\nSummer research intern, May 2016\u2013Aug 2016<\/td>\n<\/tr>\n
        Jeff Xu<\/td>\nHigh school research intern, June 2017\u2013Sep 2017<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

        Academic Service<\/h2>\n
        \n\n\n\n\n\n\n\n
        Leadership activities:<\/td>\nAMS Atmospheric and Oceanic Fluid Dynamics (AOFD) Committee, Jan 2024 \u2013<\/td>\n<\/tr>\n
        <\/td>\nAMS Oceanic Research Awards (ORA) Committee, Apr 2024\u2013<\/td>\n<\/tr>\n
        <\/td>\nFounder, Annual California Geophysical Fluid Dynamics (CalGFD) Meeting 2019\u2013Present, and Lead Organizer, 2019\u20132020<\/td>\n<\/tr>\n
        <\/td>\nAssociate Editor, Journal of Physical Oceanography, Aug 2020\u2013Dec 2024<\/td>\n<\/tr>\n
        <\/td>\nEditor, Journal of Physical Oceanography, Jan 2025\u2013<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n\n\n\n\n
        Proposal review panelist:<\/td>\nNSF Physical Oceanography\u00d7<\/span>2<\/td>\n<\/tr>\n
        <\/td>\nNSF Polar Glaciology<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n\n\n\n\n\n\n\n
        Proposal reviewer:<\/td>\nNSF Physical Oceanography<\/td>\n<\/tr>\n
        <\/td>\nNSF Arctic Natural Sciences<\/td>\n<\/tr>\n
        <\/td>\nNSF Antarctic Ocean and Atmospheric Sciences<\/td>\n<\/tr>\n
        <\/td>\nNSF Antarctic Integrated System Science<\/td>\n<\/tr>\n
        <\/td>\nIsraeli\u2013US Binational Science Foundation<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n\n\n\n\n\n\n\n
        Conference service:<\/td>\nLead Convener, Ice-ocean interactions and circulation around the Antarctic margins<\/q><\/em>, AGU Ocean Sciences Meeting 2016, 2018, 2020 and 2022<\/td>\n<\/tr>\n
        <\/td>\nChair, The Meridional Overturning Circulation<\/q><\/em>, IAPSO Symposium, 2023 IUGG Meeting<\/td>\n<\/tr>\n
        <\/td>\nCo-Convener, The Southern Ocean: Where Ocean, Ice and Atmosphere Meet<\/q><\/em>, IAPSO Symposium, 2019 IUGG Meeting<\/td>\n<\/tr>\n
        <\/td>\nChair, Submesoscale Ocean Dynamics \u2014 Part II<\/q><\/em>, 21st<\/sup> Conference on Atmospheric and Oceanic Fluid Dynamics<\/td>\n<\/tr>\n
        <\/td>\nChair, Balance\/Imbalance in the Atmosphere and Ocean<\/q><\/em>, 19th<\/sup> Conference on Atmospheric and Oceanic Fluid Dynamics<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
        Journal reviewer:<\/td>\nNature<\/em><\/td>\n<\/tr>\n
        <\/td>\nProceedings of the National Academy of Sciences<\/em><\/td>\n<\/tr>\n
        <\/td>\nScience Advances<\/em><\/td>\n<\/tr>\n
        <\/td>\nNature Climate Change<\/em><\/td>\n<\/tr>\n
        <\/td>\nNature Communications<\/em><\/td>\n<\/tr>\n
        <\/td>\nAGU Advances<\/em><\/td>\n<\/tr>\n
        <\/td>\nScientific Reports<\/em><\/td>\n<\/tr>\n
        <\/td>\nGeophysical Research Letters<\/em><\/td>\n<\/tr>\n
        <\/td>\nReviews of Geophysics<\/em><\/td>\n<\/tr>\n
        <\/td>\nJournal of Climate<\/em><\/td>\n<\/tr>\n
        <\/td>\nClimate Dynamics<\/em><\/td>\n<\/tr>\n
        <\/td>\nJournal of Physical Oceanography<\/em><\/td>\n<\/tr>\n
        <\/td>\nJournal of the Atmospheric Sciences<\/em><\/td>\n<\/tr>\n
        <\/td>\nJournal of Advances in Modeling Earth Systems<\/em><\/td>\n<\/tr>\n
        <\/td>\nJournal of Geophysical Research \u2014 Oceans<\/em><\/td>\n<\/tr>\n
        <\/td>\nJournal of Fluid Mechanics<\/em><\/td>\n<\/tr>\n
        <\/td>\nGeoscientific Model Development<\/em><\/td>\n<\/tr>\n
        <\/td>\nBiogeosciences<\/em><\/td>\n<\/tr>\n
        <\/td>\nThe Cryosphere<\/em><\/td>\n<\/tr>\n
        <\/td>\nPhilosophical Transactions A<\/em><\/td>\n<\/tr>\n
        <\/td>\nAdvances in Atmospheric Sciences<\/em><\/td>\n<\/tr>\n
        <\/td>\nTellus A: Dynamic Meteorology and Oceanography<\/em><\/td>\n<\/tr>\n
        <\/td>\nGeophysical and Astrophysical Fluid Dynamics<\/em><\/td>\n<\/tr>\n
        <\/td>\nAnnales Geophysicae<\/em><\/td>\n<\/tr>\n
        <\/td>\nOcean Science<\/em><\/td>\n<\/tr>\n
        <\/td>\nNumerische Mathematik<\/em><\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

        Seminars and Conference Abstracts (Presenter)<\/h2>\n
        \n
          \n

        1. Fate of heat approaching “dense” Antarctic ice shelves mediated by continental shelf eddies<\/q><\/em><\/span>, 2026 AGU Ocean Sciences Meeting, 27th<\/sup> February 2026.<\/p><\/li>\n

        2. An Idealized Framework for the Regimes and Dynamics of Ice Shelf Cavity Circulation<\/q><\/em><\/span>, 2026 AGU Ocean Sciences Meeting, 26th<\/sup> February 2026.<\/p><\/li>\n

        3. Oceanic melting of Antarctic glaciers: does the tail wag the dog?<\/q><\/em><\/span>, CASPO Seminar at Scripps Institution of Oceanography, 8th<\/sup> October 2025.<\/p><\/li>\n

        4. Oceanic melting of Antarctic glaciers: does the tail wag the dog?<\/q><\/em><\/span>, Atmosphere Ocean Science Colloquium, New York University, 7th<\/sup> May 2025.<\/p><\/li>\n

        5. Oceanic melting of Antarctic glaciers: does the tail wag the dog?<\/q><\/em><\/span>, Seminar in the Department of Earth Sciences, University of Oxford, 22nd<\/sup> April 2025.<\/p><\/li>\n

        6. Melt-driven transport of oceanic heat toward the Antarctic ice sheet<\/q><\/em><\/span>, Atmospheric and Oceanic Sciences Colloquium, University of Wisconsin\u2014Madison, 23rd<\/sup> September 2024.<\/p><\/li>\n

        7. Transport of oceanic heat toward floating and marine-terminating glaciers driven by melt-induced vorticity forcing<\/q><\/em><\/span>, Earth and Environmental Sciences Seminar, University of St Andrews, 24th<\/sup> July 2024.<\/p><\/li>\n

        8. Mesoscale eddy rectification as a driver of eastern boundary undercurrents<\/q><\/em><\/span>, 24th<\/sup> Conference on Atmospheric and Oceanic Fluid Dynamics, 27th<\/sup> June 2024.<\/p><\/li>\n

        9. Can we monitor Southern Ocean overturning circulation variability via remote sensing?<\/q><\/em><\/span>, Observing the Dynamics of the Southern Ocean workshop, Scripps Institution of Oceanography, 18th<\/sup> April 2024.<\/p><\/li>\n

        10. Mesoscale eddy rectification as a driver of eastern boundary undercurrents<\/q><\/em><\/span>, 2024 AGU Ocean Sciences Meeting, 22nd<\/sup> February 2024.<\/p><\/li>\n

        11. Mid-depth Ventilation of the Antarctic Margins<\/q><\/em><\/span>, 2024 AGU Ocean Sciences Meeting, 20th<\/sup> February 2024.<\/p><\/li>\n

        12. Melt-driven transport of oceanic heat toward west Antarctic ice shelves<\/q><\/em><\/span>, Icy Lunch Seminar, The University of Edinburgh, 8th<\/sup> August 2023.<\/p><\/li>\n

        13. Antarctic slope undercurrent and onshore heat transport driven by meltwater upwelling<\/q><\/em><\/span>, 2023 IUGG Meeting, Berlin, 13th<\/sup> July 2023.<\/p><\/li>\n

        14. Indirect inference of Meridional Overturning Circulation variability using satellite observables<\/q><\/em><\/span>, 2023 IUGG Meeting, Berlin, 13th<\/sup> July 2023.<\/p><\/li>\n

        15. Mechanisms and consequences of cross-slope exchange around the Antarctic Margins<\/q><\/em><\/span>, 2023 Gordon Research Conference on Coastal Ocean Dynamics, Bryant University, Rhode Island, 20th<\/sup> June 2023.<\/p><\/li>\n

        16. Isolating feedbacks between polar ocean circulation and ice melt<\/q><\/em><\/span>, Department of Earth System Science Seminar, University of California, Irvine, 25th<\/sup> January 2023.<\/p><\/li>\n

        17. Saturation of the Antarctic Circumpolar Current transport by mesoscale eddies vs.\u00a0standing waves<\/q><\/em><\/span>, 2022 Model Hierarchies Workshop, Stanford University, 31st<\/sup> August 2022.<\/p><\/li>\n

        18. Eddy<\/q><\/span> saturation of the Antarctic Circumpolar Current by standing waves<\/q><\/em><\/span>, 4th<\/sup> California Geophysical Fluid Dynamics (CalGFD) Meeting, 19th<\/sup> August 2022.<\/p><\/li>\n

        19. Eddy<\/q><\/span> saturation of the Antarctic Circumpolar Current by standing waves<\/q><\/em><\/span>, 23rd<\/sup> AMS Conference on Atmospheric and Oceanic Fluid Dynamics, 13th<\/sup> June 2022.<\/p><\/li>\n

        20. High-frequency fluctuations in Antarctic Bottom Water transport driven by Southern Ocean winds<\/q><\/em><\/span>, 2022 AGU Ocean Sciences Meeting, 4th<\/sup> February 2022.<\/p><\/li>\n

        21. High-frequency fluctuations in Antarctic Bottom Water transport driven by Southern Ocean winds<\/q><\/em><\/span>, AGU Fall Meeting, 13th<\/sup> December 2021.<\/p><\/li>\n

        22. High-frequency fluctuations in Antarctic Bottom Water transport driven by Southern Ocean winds<\/q><\/em><\/span>, British Antarctic Survey Polar Oceans Seminar, 3rd<\/sup> November 2021.<\/p><\/li>\n

        23. Mesoscale, tidal and seasonal\/interannual drivers of the Weddell Sea overturning circulation<\/q><\/em><\/span>, US Scientific Committee on Antarctic Research (US-SCAR) Conference, July 2021.<\/p><\/li>\n

        24. Bi-stability of the Filchner-Ronne Ice Shelf Cavity Circulation and Basal Melt Rates<\/q><\/em><\/span>, AGU Fall Meeting, December 2020.<\/p><\/li>\n

        25. Drivers of sea ice transport in the Antarctic Slope Current<\/q><\/em><\/span>, 2020 Scientific Committee on Antarctic Research Online Meeting, 28th<\/sup> July 2020.<\/p><\/li>\n

        26. Bi-stability of the Filchner-Ronne Ice Shelf Cavity Circulation and Basal Melt Rates<\/q><\/em><\/span>, 2020 Scientific Committee on Antarctic Research Online Meeting, July 2020.<\/p><\/li>\n

        27. Bathymetry-Aware Parameterizations of Eddy Buoyancy Fluxes<\/q><\/em><\/span>, 2020 AGU Ocean Sciences Conference, San Diego, 17th<\/sup> February 2020.<\/p><\/li>\n

        28. Bi-stability of the Filchner-Ronne Ice Shelf Cavity Circulation and Basal Melt Rates<\/q><\/em><\/span>, 2020 AGU Ocean Sciences Conference, San Diego, 18th<\/sup> February 2020.<\/p><\/li>\n

        29. What drives the Antarctic Slope Current?<\/q><\/em><\/span>, 2020 AGU Ocean Sciences Conference, San Diego, 20th<\/sup> February 2020.<\/p><\/li>\n

        30. What drives the Antarctic Slope Current?<\/q><\/em><\/span>, IAPSO Symposium, 2019 IUGG Meeting, 14th<\/sup> July 2019.<\/p><\/li>\n

        31. Tidal-\/eddy-driven circulation and heat transfer around Antarctica<\/q><\/em><\/span>, TABASCO Workshop, California Institute of Technology, 10th<\/sup> June 2019.<\/p><\/li>\n

        32. Tidal-\/eddy-driven circulation and heat transfer on the continental shelf of Antarctica<\/q><\/em><\/span>, Seminar at the National Oceanography Center, Liverpool, 9th<\/sup> May 2019.<\/p><\/li>\n

        33. Does sea ice drive the Antarctic Slope Current?<\/q><\/em><\/span>, AGU Fall Meeting, 12th<\/sup> December 2018.<\/p><\/li>\n

        34. Ocean circulation at the Antarctic margins: local dynamics with outsized climate impacts<\/q><\/em><\/span>, Sack Lunch Seminar, Massachusetts Institute of Technology, 17th<\/sup> October 2018.<\/p><\/li>\n

        35. Ocean circulation at the Antarctic margins: local dynamics with outsized climate impacts<\/q><\/em><\/span>, ClimaTea Seminar, Harvard University, 16th<\/sup> October 2018.<\/p><\/li>\n

        36. Circum-Antarctic eddy\/tidal overturning and shoreward heat transport<\/q><\/em><\/span>, POLAR 2018 Meeting, Davos, Switzerland, 20th<\/sup> June 2018.<\/p><\/li>\n

        37. Dynamics of heat transfer and exchanges across the Antarctic Slope Front<\/q><\/em><\/span>, AOPP seminar, University of Oxford, 14th<\/sup> June 2018.<\/p><\/li>\n

        38. Dynamics of heat transfer and exchanges across the Antarctic Slope Front<\/q><\/em><\/span>, Polar ocean seminar series, British Antarctic Survey, Cambridge, 13th<\/sup> June 2018.<\/p><\/li>\n

        39. Computational Modeling Challenges at the Ocean\u2019s (Southern) High Latitudes<\/q><\/em><\/span>, Workshop on The Future of Earth System Modeling: Atmosphere, Oceans, and Computational Infrastructure, California Institute of Technology, 17th<\/sup> May 2018.<\/p><\/li>\n

        40. Dynamics of heat transfer and exchanges across the Antarctic Slope Front<\/q><\/em><\/span>, CASPO Seminar at Scripps Institution of Oceanography, 2nd<\/sup> May 2018.<\/p><\/li>\n

        41. Eddy\/tidal overturning and heat transport across the Antarctic Slope Front<\/q><\/em><\/span>, 2018 AGU Ocean Sciences Conference, 14th<\/sup> February 2018.<\/p><\/li>\n

        42. Reshaping the Antarctic Circumpolar Current via Antarctic Bottom Water Export<\/q><\/em><\/span>,
          \n21st<\/sup> Conference on Atmospheric and Oceanic Fluid Dynamics, 29th<\/sup> June 2017.<\/p><\/li>\n

        43. Eddy\/tidal mixing and transport at the Antarctic margins<\/q><\/em><\/span>, Southern Ocean Workshop, NCAR, 10th<\/sup> April 2017.<\/p><\/li>\n

        44. Eddy\/tidal mixing and transport at the Antarctic margins<\/q><\/em><\/span>, RSES Seminar at the Australian National University, 3rd<\/sup> November 2016.<\/p><\/li>\n

        45. Eddy\/tidal mixing and transport at the Antarctic margins<\/q><\/em><\/span>, Fluid Dynamics Seminar at the University of New South Wales, 31st<\/sup> October 2016.<\/p><\/li>\n

        46. Eddy\/tidal mixing and transport at the Antarctic margins<\/q><\/em><\/span>, ROMS Asia-Pacific Workshop, University of Tasmania, 18th<\/sup> October 2016.<\/p><\/li>\n

        47. Eddy\/tidal mixing and transport at the Antarctic margins<\/q><\/em><\/span>, AOS Seminar at GFDL, Princeton 4th<\/sup> October 2016.<\/p><\/li>\n

        48. Eddy\/tidal mixing and transport at the Antarctic margins<\/q><\/em><\/span>, Department of Marine and Coastal Sciences Seminar at Rutgers University, 3rd<\/sup> October 2016.<\/p><\/li>\n

        49. Eddy mixing and transport at the Antarctic margins<\/q><\/em><\/span>, Jim McWilliams 70th<\/sup> Birthday Symposium, NCAR, 24th<\/sup> August 2016.<\/p><\/li>\n

        50. Reshaping the Antarctic Circumpolar Current via Antarctic Bottom Water Formation<\/q><\/em><\/span>, 2016 AGU Ocean Sciences Conference, 22nd<\/sup> February 2016.<\/p><\/li>\n

        51. Turbulent Water Mass Exchanges Across the Antarctic Continental Slope<\/q><\/em><\/span>, Submesoscale Dynamics and Biology over Steep Slopes (SYNBIOS) symposium, Ecole Normale Sup\u00e9riuere, Paris, 6th<\/sup> July 2015.<\/p><\/li>\n

        52. Eddy Energetics and Momentum Transfer on the Antarctic Continental Slope<\/q><\/em><\/span>,
          \n20th<\/sup> Conference on Atmospheric and Oceanic Fluid Dynamics, June 2015.<\/p><\/li>\n

        53. Eddy transport and mixing across the Antarctic continental slope<\/q><\/em><\/span>, Sack Lunch Seminar at MIT, 13th<\/sup> May 2015.<\/p><\/li>\n

        54. Mesoscale Eddy Mixing Across the Antarctic Shelf Break<\/q><\/em><\/span>, Southern Ocean Dynamics and Biogeochemistry Workshop, Caltech, 4th<\/sup> February 2014.<\/p><\/li>\n

        55. Eddy-Mediated Transport of Circumpolar Deep Water Across the Antarctic Shelf Break<\/q><\/em><\/span>, AGU Fall Meeting, 18th<\/sup> December 2014.<\/p><\/li>\n

        56. Eddy-Mediated Transport of Circumpolar Deep Water Across the Antarctic Shelf Break<\/q><\/em><\/span>, Caltech\/JPL workshop on Sea Level Change, 4th<\/sup> September 2014.<\/p><\/li>\n

        57. Water Mass Exchange and Heat Transport Across the Antarctic Shelf Break<\/q><\/em><\/span>, Ocean Group Seminar at the NASA Jet Propulsion Laboratory, 20th<\/sup> May 2014.<\/p><\/li>\n

        58. Water Mass Exchange and Heat Transport Across the Antarctic Shelf Break<\/q><\/em><\/span>, Yuk Lunch Seminar at California Institute of Technology, 6th<\/sup> May 2014.<\/p><\/li>\n

        59. Water mass exchange across the Antarctic Slope Front<\/q><\/em><\/span>, 2014 AGU Ocean Sciences Conference, February 2014.<\/p><\/li>\n

        60. A model for the structure and overturning of the Antarctic Slope Front<\/q><\/em><\/span>, 19th Conference on Atmospheric and Oceanic Fluid Dynamics, June 2013.<\/p><\/li>\n

        61. Connecting Antarctic cross-slope exchange with Southern Ocean overturning<\/q><\/em><\/span>, Atmospheric and Oceanic Sciences Seminar at University of California, Los Angeles, 28th<\/sup> February 2013.<\/p><\/li>\n

        62. Regulation of the ocean\u2019s deep overturning circulation by Antarctic easterly winds<\/q><\/em><\/span>, Environmental Science and Engineering Seminar at California Institute of Technology, 20th<\/sup> February 2013.<\/p><\/li>\n

        63. Deep overturning sensitivity to easterly winds over the Antarctic continental slope<\/q><\/em><\/span>, MIT Southern Ocean Workshop, 29th<\/sup> January 2013.<\/p><\/li>\n

        64. Export of Antarctic Bottom Water and overturning circulation in the Southern Ocean<\/q><\/em><\/span>, Physics of Oceans and Atmospheres Seminar at Oregon State University, 19th<\/sup> July 2012.<\/p><\/li>\n

        65. Sensitivity of Antarctic Bottom Water export and overturning circulation to polar easterlies<\/q><\/em><\/span>, XXXII SCAR Open Science Conference, 18th<\/sup> July 2012.<\/p><\/li>\n

        66. Sensitivity of Antarctic Bottom Water export and overturning circulation to polar easterlies<\/q><\/em><\/span>, NCAR IMAGE Theme of the Year 2012: Connections between Rotating, Stratified Turbulence and Climate: Theory, Observations, Experiments, and Models, 15th<\/sup> May 2012.<\/p><\/li>\n

        67. Antarctic Bottom Water: downwelling and cross-equatorial flow<\/q><\/em><\/span>, Ocean Group Seminar at the NASA Jet Propulsion Laboratory, 10th<\/sup> January 2012.<\/p><\/li>\n

        68. Cross-equatorial flow of the Antarctic Bottom Water under the complete Coriolis force<\/q><\/em><\/span>, Seminar at the Summer Program in Geophysical Fluid Dynamics at Woods Hole Oceanographic Institution, 22nd<\/sup> July 2011.<\/p><\/li>\n

        69. Inertial and topographic steering of abyssal and coastal ocean currents<\/q><\/em><\/span>, Vortex Dynamics Group Seminar, University of St Andrews, 19th<\/sup> April 2011<\/p><\/li>\n

        70. Cross-equatorial flow of abyssal ocean currents with a complete representation of the Coriolis force<\/q><\/em><\/span> (Lighthill-Thwaites Prize mini-symposium), British Applied Mathematics Colloquium, 12th<\/sup> April 2011<\/p><\/li>\n

        71. A numerical study of cross-equatorial abyssal ocean currents with a complete representation of the Coriolis force<\/q><\/em><\/span>, European Geosciences Union General Assembly, 4th<\/sup> April 2011<\/p><\/li>\n

        72. The role of the complete Coriolis force in cross-equatorial transport of abyssal currents: some numerical results<\/q><\/em><\/span>, Dynamics of Rotating Fluids, University College London, 7th<\/sup> January 2011<\/p><\/li>\n

        73. Cross-equatorial flow of Antarctic Bottom Water and the complete Coriolis force<\/q><\/em><\/span>, 63rd<\/sup> Annual Meeting of the APS Division of Fluid Dynamics, Long Beach, California, 22nd<\/sup> November 2010<\/p><\/li>\n

        74. The role of the complete Coriolis force in cross-equatorial transport of the Antarctic Bottom Water<\/q><\/em><\/span>, CASPO Seminar, Scripps Institute of Oceanography, 17th<\/sup> November 2010<\/p><\/li>\n

        75. The role of the complete Coriolis force in cross-equatorial transport of the Antarctic Bottom Water<\/q><\/em><\/span>, Challenger Ocean Modelling Group Meeting, National Oceanography Centre, Southampton, September 2010<\/p><\/li>\n

        76. Experiments on nonlinear coastal shelf waves in a rotating annulus<\/q><\/em><\/span>, European Geosciences Union General Assembly, May 2010 (poster presentation)<\/em><\/span><\/p><\/li>\n

        77. The role of the complete Coriolis force in cross-equatorial transport of the Antarctic Bottom Water<\/q><\/em><\/span>, European Geosciences Union General Assembly, May 2010 (solicited talk)<\/em><\/span><\/p><\/li>\n

        78. Numerical simulation of wave propagation along a discontinuity in depth in a rotating annulus<\/q><\/em><\/span>, Institute for Computational Fluid Dynamics Conference on Numerical Methods for Fluid Dynamics, April 2010<\/p><\/li>\n

        79. The role of the complete Coriolis force in cross-equatorial transport of the Antarctic Bottom Water<\/q><\/em><\/span>, British Applied Mathematics Colloquium, Maxwell Institute for Mathematical Sciences, April 2010<\/p><\/li>\n

        80. Nonlinear Rossby shelf waves in a rotating annulus<\/q><\/em><\/span>, Dynamics of Rotating Fluids, University College London, January 2010<\/p><\/li>\n

        81. \u201c<\/span>Non-traditional<\/q>\u2019 shallow water models for equatorial ocean currents\u2019<\/em><\/span>, Challenger Ocean Modelling Group Meeting, University of Oxford, September 2009<\/p><\/li>\n

        82. \u201c<\/span>Non-traditional<\/q>\u2019 shallow water models for equatorial ocean currents\u2019<\/em><\/span>, British Applied Mathematics Colloquium, University of Nottingham, April 2009<\/p><\/li>\n

        83. Multilayer shallow water equations on a nontraditional \u03b2<\/em><\/span>-plane<\/q><\/em><\/span>, Dynamics of Rotating Fluids, University College London, January 2009<\/p><\/li>\n

        84. Two-layer obliquely-rotating shallow water equations with complete Coriolis force<\/q><\/em><\/span>, EUROMECH Fluid Mechanics Conference 7, University of Manchester, September 2008<\/p><\/li>\n

        85. Two-layer shallow water equations with complete Coriolis force and topography<\/q><\/em><\/span>, European Consortium for Mathematics in Industry, University College London, June 2008<\/p><\/li>\n<\/ol>\n

          \u00a0<\/p>\n","protected":false},"excerpt":{"rendered":"

          (This is an automated HTML version of my LaTeX CV, generated using Python and Pandoc, with a little help from ChatGPT. Please contact me for a PDF version of my CV.) Andrew Stewart 2026-03-06 Professor Department of Atmospheric and Oceanic Sciences University of California, Los Angeles Los Angeles, CA 90095 1-310-825-1751 Employment Jul 2023 \u2013…<\/p>\n","protected":false},"author":41,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-613","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/pages\/613","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\/41"}],"replies":[{"embeddable":true,"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/comments?post=613"}],"version-history":[{"count":19,"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/pages\/613\/revisions"}],"predecessor-version":[{"id":638,"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/pages\/613\/revisions\/638"}],"wp:attachment":[{"href":"https:\/\/atmos.ucla.edu\/dynamical-oceanography-group\/wp-json\/wp\/v2\/media?parent=613"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}