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\n  \n 2025\n \n \n (5)\n \n \n
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\n \n\n \n \n \n \n \n Saturation of Internal Tide Generation over Shallow Supercritical Topography.\n \n \n \n\n\n \n Chang, J.; and Klymak, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr., 55(3): 293–315. 2025.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n  \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  changklymak25,\n  Title\t\t= {Saturation of {{Internal Tide Generation}} over {{Shallow\n\t\t  Supercritical Topography}}},\n  Author\t= {Chang, Jia-Xuan and Klymak, Jody M.},\n  Year\t\t= {2025},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {55},\n  Number\t= {3},\n  Pages\t\t= {293--315},\n  DOI\t\t= {10.1175/JPO-D-24-0088.1},\n  URLDate\t= {2025-05-14},\n  Abstract\t= {Abstract Understanding the conversion of surface tides\n\t\t  into internal tides and the resulting turbulence is\n\t\t  important for oceanic mixing. This study investigates\n\t\t  internal tide generation over shallow supercritical\n\t\t  obstacles in flows, where Nh / U 0 {$\\sim$} O (1), with N\n\t\t  being background stratification, h being obstacle height,\n\t\t  and U 0 being far-field tidal velocity amplitude,\n\t\t  particularly relevant in shallow, fjord-like environments\n\t\t  where tidal currents become much faster. Previous work has\n\t\t  focused on Nh / U 0 {$\\gg$} 1, showing that internal tide\n\t\t  generation roughly follows and local dissipation follows .\n\t\t  Here, a faster, linear stratified flow regime is\n\t\t  investigated using idealized simulations. Tidal energy\n\t\t  conversion follows the power law until the crest-top Froude\n\t\t  number Fr c = U c / c 1 {$\\approx$} 1 [where U c = U 0 H /(\n\t\t  H - h ) is the barotropic flow speed at the crest, H is the\n\t\t  total water depth, and is the mode-1 phase speed in the\n\t\t  deep water], beyond which internal tide generation stops\n\t\t  increasing (saturates). Radiation saturates and local\n\t\t  dissipation no longer grows as quickly as . Qualitatively,\n\t\t  the fully stratified flow with Fr c {$>$} 1 at the crest\n\t\t  resembles approach-controlled flow in two layers. Radiation\n\t\t  from the crest transitions from a relatively linear\n\t\t  response with well-defined internal tidal beams to a\n\t\t  strongly nonlinear response with diffuse beam as Fr c {$>$}\n\t\t  1. However, significant mode-1 internal tides are still\n\t\t  radiated into the far field, contradicting the traditional\n\t\t  dichotomy that basins with Fr c {$>$} 1 do not generate\n\t\t  internal tides. Simulations with realistic or asymmetric\n\t\t  stratification exhibit the same general characteristics as\n\t\t  constant-stratification simulations. This saturation\n\t\t  conversion when Fr c {$>$} 1 should be considered when\n\t\t  devising wave-drag parameterization used in the models,\n\t\t  especially in fjord regions where large Fr c values are\n\t\t  likely to be found. Significance Statement Tidal forcing of\n\t\t  stratified flow over a submarine ridge produces internal\n\t\t  waves at the tidal frequency and local turbulence. For\n\t\t  moderate tides, the energy removed from the surface tide\n\t\t  usually scales quadratically with the flow amplitude. Here,\n\t\t  we show that when the flow speed above the ridge crest\n\t\t  exceeds the speed of the lowest internal wave mode, the\n\t\t  conversion rate stops increasing, and both internal tide\n\t\t  radiation and local dissipation no longer increase with\n\t\t  stronger forcing. This regime should be taken into account\n\t\t  when parameterizing internal tidal drag and mixing,\n\t\t  particularly when they are parameterized in shallow seas\n\t\t  and fjords.},\n  copyright\t= {http://www.ametsoc.org/PUBSReuseLicenses},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/QB5P73EA/Chang and Klymak -\n\t\t  2025 - Saturation of Internal Tide Generation over Shallow\n\t\t  Supercritical Topography.pdf}\n}\n\n
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\n Abstract Understanding the conversion of surface tides into internal tides and the resulting turbulence is important for oceanic mixing. This study investigates internal tide generation over shallow supercritical obstacles in flows, where Nh / U 0 $∼$ O (1), with N being background stratification, h being obstacle height, and U 0 being far-field tidal velocity amplitude, particularly relevant in shallow, fjord-like environments where tidal currents become much faster. Previous work has focused on Nh / U 0 $≫$ 1, showing that internal tide generation roughly follows and local dissipation follows . Here, a faster, linear stratified flow regime is investigated using idealized simulations. Tidal energy conversion follows the power law until the crest-top Froude number Fr c = U c / c 1 $≈$ 1 [where U c = U 0 H /( H - h ) is the barotropic flow speed at the crest, H is the total water depth, and is the mode-1 phase speed in the deep water], beyond which internal tide generation stops increasing (saturates). Radiation saturates and local dissipation no longer grows as quickly as . Qualitatively, the fully stratified flow with Fr c $>$ 1 at the crest resembles approach-controlled flow in two layers. Radiation from the crest transitions from a relatively linear response with well-defined internal tidal beams to a strongly nonlinear response with diffuse beam as Fr c $>$ 1. However, significant mode-1 internal tides are still radiated into the far field, contradicting the traditional dichotomy that basins with Fr c $>$ 1 do not generate internal tides. Simulations with realistic or asymmetric stratification exhibit the same general characteristics as constant-stratification simulations. This saturation conversion when Fr c $>$ 1 should be considered when devising wave-drag parameterization used in the models, especially in fjord regions where large Fr c values are likely to be found. Significance Statement Tidal forcing of stratified flow over a submarine ridge produces internal waves at the tidal frequency and local turbulence. For moderate tides, the energy removed from the surface tide usually scales quadratically with the flow amplitude. Here, we show that when the flow speed above the ridge crest exceeds the speed of the lowest internal wave mode, the conversion rate stops increasing, and both internal tide radiation and local dissipation no longer increase with stronger forcing. This regime should be taken into account when parameterizing internal tidal drag and mixing, particularly when they are parameterized in shallow seas and fjords.\n
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\n \n\n \n \n \n \n \n Regression-Based Characterization of the Marine Carbonate System across Shelf and Nearshore Waters of Queen Charlotte Sound.\n \n \n \n\n\n \n Hare, A.; Evans, W.; Dosser, H.; Jackson, J.; Alin, S.; Hannah, C.; Ross, T.; and Klymak, J.\n\n\n \n\n\n\n Marine Chemistry, 270: 104511. 2025.\n \n\n\n\n
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@Article{\t  hareetal25,\n  Title\t\t= {Regression-Based Characterization of the Marine Carbonate\n\t\t  System across Shelf and Nearshore Waters of {{Queen\n\t\t  Charlotte Sound}}},\n  Author\t= {Hare, A.A. and Evans, W. and Dosser, H.V. and Jackson,\n\t\t  J.M. and Alin, S.R. and Hannah, C. and Ross, T. and Klymak,\n\t\t  J.M.},\n  Year\t\t= {2025},\n  Journal\t= {Marine Chemistry},\n  Volume\t= {270},\n  Pages\t\t= {104511},\n  DOI\t\t= {10.1016/j.marchem.2025.104511},\n  URLDate\t= {2025-05-18},\n  langid\t= {english},\n  Keywords\t= {cproofrefereed,jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/S7BCEW2N/Hare et al. - 2025\n\t\t  - Regression-based characterization of the marine carbonate\n\t\t  system across shelf and nearshore waters o.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Predicting Upwelling Due to Down-Fjord Winds.\n \n \n \n\n\n \n Klymak, J. M.; Jackson, J. M.; and Hannah, C. G.\n\n\n \n\n\n\n J. Phys. Oceanogr., 55(9): 1553–1568. 2025.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n  \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  klymaketal25,\n  Title\t\t= {Predicting {{Upwelling}} Due to {{Down-Fjord Winds}}},\n  Author\t= {Klymak, Jody M. and Jackson, Jennifer M. and Hannah,\n\t\t  Charles G.},\n  Year\t\t= {2025},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {55},\n  Number\t= {9},\n  Pages\t\t= {1553--1568},\n  DOI\t\t= {10.1175/JPO-D-24-0176.1},\n  URLDate\t= {2025-10-10},\n  Abstract\t= {Abstract Down-fjord winds have been implicated in\n\t\t  upwelling and exchange of water in fjords. In one temperate\n\t\t  fjord, strong winds oxygenated and cooled water deeper than\n\t\t  100 m. Deep temperature minima accompanied by oxygen maxima\n\t\t  are a common feature in fjords, yet do not have a ready\n\t\t  prediction. Here, it is shown that the dominant process\n\t\t  driving the upwelling is wind-driven transport divergence\n\t\t  at the head of the fjord, as opposed to local convection\n\t\t  due to cooling or mechanical mixing. Previous work has\n\t\t  focused on two-layer approximations, but those fail to\n\t\t  differentiate the depth of upwelling if the bottom layer is\n\t\t  continuously stratified. Simulations with a constant\n\t\t  stratification show that the depth that the densest water\n\t\t  comes from is proportional to , where L is the length of\n\t\t  the fjord or the horizontal scale of the wind, is the wind\n\t\t  stress, and N 2 is the buoyancy profile. The time scale of\n\t\t  the upwelling is similarly scaled as . These scalings apply\n\t\t  over a wide range of forcings and geometry, so long as the\n\t\t  depth scale does not approach the depth of the fjord. A\n\t\t  simple procedure can be used to get a similar scaling if N\n\t\t  ( z ) is not constant. If the wind is allowed to relax, the\n\t\t  simulations come back to rest after a vigorous seiche,\n\t\t  subducting the upwelled water. Despite strong turbulence,\n\t\t  the net exchange with water outside the fjord is found to\n\t\t  be small, and oxygen concentrations are mostly modified by\n\t\t  air--sea gas exchange rather than diapycnal mixing.\n\t\t  Significance Statement Upwelling in fjords due to\n\t\t  down-fjord winds has the potential to ventilate deep water\n\t\t  and to drive exchange with water outside the fjord. Here,\n\t\t  we offer a simple method to predict the depth and time\n\t\t  scale of the upwelling based on the wind strength, the\n\t\t  initial stratification, and the length of the fjord.\n\t\t  Vertical mixing has only a minor impact on the vertical\n\t\t  distribution of properties in the fjord due to the wind\n\t\t  events, and much of the transport into the fjord is\n\t\t  reversible in the absence of other mixing sources.},\n  copyright\t= {http://www.ametsoc.org/PUBSReuseLicenses},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/3UUYTMIM/Klymak et al. -\n\t\t  2025 - Predicting Upwelling due to Down-Fjord Winds.pdf}\n}\n\n
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\n Abstract Down-fjord winds have been implicated in upwelling and exchange of water in fjords. In one temperate fjord, strong winds oxygenated and cooled water deeper than 100 m. Deep temperature minima accompanied by oxygen maxima are a common feature in fjords, yet do not have a ready prediction. Here, it is shown that the dominant process driving the upwelling is wind-driven transport divergence at the head of the fjord, as opposed to local convection due to cooling or mechanical mixing. Previous work has focused on two-layer approximations, but those fail to differentiate the depth of upwelling if the bottom layer is continuously stratified. Simulations with a constant stratification show that the depth that the densest water comes from is proportional to , where L is the length of the fjord or the horizontal scale of the wind, is the wind stress, and N 2 is the buoyancy profile. The time scale of the upwelling is similarly scaled as . These scalings apply over a wide range of forcings and geometry, so long as the depth scale does not approach the depth of the fjord. A simple procedure can be used to get a similar scaling if N ( z ) is not constant. If the wind is allowed to relax, the simulations come back to rest after a vigorous seiche, subducting the upwelled water. Despite strong turbulence, the net exchange with water outside the fjord is found to be small, and oxygen concentrations are mostly modified by air–sea gas exchange rather than diapycnal mixing. Significance Statement Upwelling in fjords due to down-fjord winds has the potential to ventilate deep water and to drive exchange with water outside the fjord. Here, we offer a simple method to predict the depth and time scale of the upwelling based on the wind strength, the initial stratification, and the length of the fjord. Vertical mixing has only a minor impact on the vertical distribution of properties in the fjord due to the wind events, and much of the transport into the fjord is reversible in the absence of other mixing sources.\n
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\n \n\n \n \n \n \n \n Ocean Gliders for Planning and Monitoring Remote Canadian Pacific Marine Protected Areas.\n \n \n \n\n\n \n Ross, T.; Dosser, H.; Klymak, J.; Evans, W.; Hare, A.; Jackson, J.; and Waterman, S.\n\n\n \n\n\n\n Oceanog. 2025.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n  \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n \n \n\n\n\n
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@Article{\t  rossetal25,\n  Title\t\t= {Ocean {{Gliders}} for {{Planning}} and {{Monitoring Remote\n\t\t  Canadian Pacific Marine Protected Areas}}},\n  Author\t= {Ross, Tetjana and Dosser, Hayley and Klymak, Jody and\n\t\t  Evans, Wiley and Hare, Alex and Jackson, Jennifer and\n\t\t  Waterman, Stephanie},\n  Year\t\t= {2025},\n  Journal\t= {Oceanog},\n  DOI\t\t= {10.5670/oceanog.2025e104},\n  URLDate\t= {2025-05-18},\n  Abstract\t= {Given the United Nations' ambitious goal---endorsed by\n\t\t  more than 100 nations, including Canada---of protecting\n\t\t  30\\% of the world's marine ecosystems by 2030 (UN, 2023),\n\t\t  the need to establish, expand, and track the effectiveness\n\t\t  of protected areas is becoming more pressing each year.\n\t\t  Effective planning for and monitoring of marine protected\n\t\t  areas (MPAs) rely on the availability of quality baseline\n\t\t  ecological and oceanographic information. Many of the sites\n\t\t  in the Canadian Pacific Ocean best suited for protection,\n\t\t  due to the confluence of ecological, cultural, and\n\t\t  political significance, are remote. This poses two\n\t\t  challenges: (1) there is little baseline information to\n\t\t  guide planning, and (2) they are challenging to monitor\n\t\t  once established.},\n  Keywords\t= {cproofrefereed,jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/ZUKY9TV2/Fisheries and\n\t\t  Oceans Canada et al. - 2025 - Ocean Gliders for Planning\n\t\t  and Monitoring Remote Canadian Pacific Marine Protected\n\t\t  Areas.pdf}\n}\n\n
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\n Given the United Nations' ambitious goal—endorsed by more than 100 nations, including Canada—of protecting 30% of the world's marine ecosystems by 2030 (UN, 2023), the need to establish, expand, and track the effectiveness of protected areas is becoming more pressing each year. Effective planning for and monitoring of marine protected areas (MPAs) rely on the availability of quality baseline ecological and oceanographic information. Many of the sites in the Canadian Pacific Ocean best suited for protection, due to the confluence of ecological, cultural, and political significance, are remote. This poses two challenges: (1) there is little baseline information to guide planning, and (2) they are challenging to monitor once established.\n
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\n \n\n \n \n \n \n \n Oxygen Variability on the Canadian Pacific Shelf: Trnds, Drives, and Projections in the Context of Emerging Hypoxia in Queen Charlotte Sound.\n \n \n \n\n\n \n Stevens, S.; Hannah, C.; Evans, W.; Klymak, J.; Waterman, S.; and Ross, T.\n\n\n \n\n\n\n 2025.\n \n\n\n\n
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@Misc{\t\t  stevensetal25,\n  Title\t\t= {Oxygen Variability on the {{Canadian Pacific}} Shelf:\n\t\t  Trnds, Drives, and Projections in the Context of Emerging\n\t\t  Hypoxia in {{Queen Charlotte Sound}}},\n  Author\t= {Stevens, S.W. and Hannah, C. and Evans, W. and Klymak,\n\t\t  J.M. and Waterman, S.N. and Ross, T.},\n  Year\t\t= {2025},\n  Keywords\t= {cproofrefereed,jmkrefereed},\n  Annotation\t= {Submitted to Global Biogeochemical Cycles},\n  File\t\t= {/Users/jklymak/Zotero/storage/KFJCG4PB/Stevens et al. -\n\t\t  2025 - Oxygen variability on the Canadian Pacific shelf\n\t\t  trnds, drives, and projections in the context of e.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Internal Waves Force Elevated Turbulent Mixing at Barkley Canyon.\n \n \n \n\n\n \n Anstey, K. J.; Klymak, J. M.; Mihaly, S. F.; and Thomson, R. E.\n\n\n \n\n\n\n J. Geophys. Res. Oceans, 129(7): e2023JC020760. 2024.\n e2023JC020760 2023JC020760\n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n  \n \n abstract \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
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@Article{\t  ansteyetal24,\n  Title\t\t= {Internal {{Waves Force Elevated Turbulent Mixing}} at\n\t\t  {{Barkley Canyon}}},\n  Author\t= {Anstey, Kurtis J. and Klymak, Jody M. and Mihaly, Steven\n\t\t  F. and Thomson, Richard E.},\n  Year\t\t= {2024},\n  Journal\t= {J. Geophys. Res. Oceans},\n  Volume\t= {129},\n  Number\t= {7},\n  Pages\t\t= {e2023JC020760},\n  DOI\t\t= {10.1029/2023JC020760},\n  URLDate\t= {2024-11-21},\n  Abstract\t= {Submarine canyons are hot spots for topography-internal\n\t\t  wave interactions, with elevated mixing contributing to\n\t\t  regional water mass transport and productivity. Two\n\t\t  velocity time series compare and contrast internal waves\n\t\t  deep inside Barkley Canyon to a nearby site on the\n\t\t  shelf-break slope of the Vancouver Island Continental\n\t\t  Shelf. Elevation of internal wave energy occurs near\n\t\t  topography, up to a factor of 10 above the slope and 100 in\n\t\t  the canyon. All frequency bands display strong seasonal\n\t\t  variability but weak interannual variability. Diurnal (K1)\n\t\t  energy is sub-inertial, trapped along topography, and\n\t\t  forced locally through barotropic motions. Both sites have\n\t\t  high near-inertial (NI) energy linked to wind events,\n\t\t  though fewer events are observed deep inside the canyon. At\n\t\t  the slope site, near-inertial energy is attenuated with\n\t\t  depth, while in the canyon it is amplified near the bottom.\n\t\t  Freely propagating semidiurnal (M2) energy appears focused\n\t\t  near critical shelf-break and canyon floor topography, due\n\t\t  to local and remote baroclinic forcing. The high-frequency\n\t\t  internal wave continuum has enhanced near-bottom energy at\n\t\t  both sites (up to 7 {\\texttimes} the Garrett-Munk\n\t\t  spectrum), and inferred dissipation rates, {$\\varepsilon$},\n\t\t  reaching 10-7 W kg-1 near topography. Dissipation is most\n\t\t  strongly correlated with semidiurnal energy variability at\n\t\t  both sites, with secondary contributors that are site\n\t\t  dependent. Forcing power law fits are\n\t\t  {$\\varepsilon\\sim$}M20.8+ {\\textbackslash}varepsilon\n\t\t  {\\textbackslash}sim\n\t\t  M\\_2{\\textasciicircum}0.8+{\\textbackslash} SubK10.6\n\t\t  \\{{\\textbackslash}textSub\\_K\\_1{\\textasciicircum}0.6{\\textbackslash}\n\t\t  on the slope, and {$\\varepsilon\\sim$}M21.5+\n\t\t  {\\textbackslash}varepsilon {\\textbackslash}sim\n\t\t  M\\_2{\\textasciicircum}1.5+{\\textbackslash} NI0.2 in the\n\t\t  canyon. There is also a build-up of ``shoulder'' energy\n\t\t  (PSh) near the buoyancy frequency, with a power law fit to\n\t\t  dissipation of PSh {$\\sim$} {$\\varepsilon$}0.3 at both sites.\\vphantom\\}},\n  copyright\t= {All rights reserved},\n  langid\t= {english},\n  Keywords\t= {Barkley Canyon,continental slope,internal\n\t\t  waves,jmkrefereed,mixing,submarine canyon,turbulent\n\t\t  dissipation},\n  Note\t\t= {e2023JC020760 2023JC020760},\n  File\t\t= {/Users/jklymak/Zotero/storage/X3Y2HVY6/Anstey et al. -\n\t\t  2024 - Internal Waves Force Elevated Turbulent Mixing at\n\t\t  Barkley\n\t\t  Canyon.pdf;/Users/jklymak/Zotero/storage/6ZULD53Q/2023JC020760.html}\n}\n\n
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\n Submarine canyons are hot spots for topography-internal wave interactions, with elevated mixing contributing to regional water mass transport and productivity. Two velocity time series compare and contrast internal waves deep inside Barkley Canyon to a nearby site on the shelf-break slope of the Vancouver Island Continental Shelf. Elevation of internal wave energy occurs near topography, up to a factor of 10 above the slope and 100 in the canyon. All frequency bands display strong seasonal variability but weak interannual variability. Diurnal (K1) energy is sub-inertial, trapped along topography, and forced locally through barotropic motions. Both sites have high near-inertial (NI) energy linked to wind events, though fewer events are observed deep inside the canyon. At the slope site, near-inertial energy is attenuated with depth, while in the canyon it is amplified near the bottom. Freely propagating semidiurnal (M2) energy appears focused near critical shelf-break and canyon floor topography, due to local and remote baroclinic forcing. The high-frequency internal wave continuum has enhanced near-bottom energy at both sites (up to 7 × the Garrett-Munk spectrum), and inferred dissipation rates, $ɛ$, reaching 10-7 W kg-1 near topography. Dissipation is most strongly correlated with semidiurnal energy variability at both sites, with secondary contributors that are site dependent. Forcing power law fits are $ɛ∼$M20.8+ \\varepsilon \\sim M_2\\textasciicircum0.8+\\ SubK10.6 \\\\textSub_K_1\\textasciicircum0.6\\ on the slope, and $ɛ∼$M21.5+ \\varepsilon \\sim M_2\\textasciicircum1.5+\\ NI0.2 in the canyon. There is also a build-up of ``shoulder'' energy (PSh) near the buoyancy frequency, with a power law fit to dissipation of PSh $∼$ $ɛ$0.3 at both sites.p̌hantom\\\n
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\n \n\n \n \n \n \n \n Observations of Tidally Driven Turbulence over Steep, Small-Scale Topography Embedded in the Tasman Slope.\n \n \n \n\n\n \n Marques, O. B.; Alford, M. H.; Pinkel, R.; MacKinnon, J. A.; Voet, G.; Klymak, J. M.; and Nash, J. D.\n\n\n \n\n\n\n J. Phys. Oceanogr., 54(2): 601–615. 2024.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n  \n \n abstract \n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  marquesetal24,\n  Title\t\t= {Observations of {{Tidally Driven Turbulence}} over\n\t\t  {{Steep}}, {{Small-Scale Topography Embedded}} in the\n\t\t  {{Tasman Slope}}},\n  Author\t= {Marques, Olavo B. and Alford, Matthew H. and Pinkel,\n\t\t  Robert and MacKinnon, Jennifer A. and Voet, Gunnar and\n\t\t  Klymak, Jody M. and Nash, Jonathan D.},\n  Year\t\t= {2024},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {54},\n  Number\t= {2},\n  Pages\t\t= {601--615},\n  DOI\t\t= {10.1175/JPO-D-23-0038.1},\n  URLDate\t= {2025-10-10},\n  Abstract\t= {Abstract Enhanced diapycnal mixing induced by the\n\t\t  near-bottom breaking of internal waves is an essential\n\t\t  component of the lower meridional overturning circulation.\n\t\t  Despite its crucial role in the ocean circulation, tidally\n\t\t  driven internal wave breaking is challenging to observe due\n\t\t  to its inherently short spatial and temporal scales. We\n\t\t  present detailed moored and shipboard observations that\n\t\t  resolve the spatiotemporal variability of the tidal\n\t\t  response over a small-scale bump embedded in the\n\t\t  continental slope of Tasmania. Cross-shore tidal currents\n\t\t  drive a nonlinear trapped response over the steep bottom\n\t\t  around the bump. The observations are roughly consistent\n\t\t  with two-dimensional high-mode tidal lee-wave theory.\n\t\t  However, the alongshore tidal velocities are large,\n\t\t  suggesting that the alongshore bathymetric variability\n\t\t  modulates the tidal response driven by the cross-shore\n\t\t  tidal flow. The semidiurnal tide and energy dissipation\n\t\t  rate are correlated at subtidal time scales, but with\n\t\t  complex temporal variability. Energy dissipation from a\n\t\t  simple scattering model shows that the elevated near-bottom\n\t\t  turbulence can be sustained by the impinging mode-1\n\t\t  internal tide, where the dissipation over the bump is O\n\t\t  (1\\%) of the incident depth-integrated energy flux. Despite\n\t\t  this small fraction, tidal dissipation is enhanced over the\n\t\t  bump due to steep topography at a horizontal scale of O (1)\n\t\t  km and may locally drive significant diapycnal mixing.\n\t\t  Significance Statement Near-bottom turbulent mixing is a\n\t\t  key element of the global abyssal circulation. We present\n\t\t  observations of the spatiotemporal variability of tidally\n\t\t  driven turbulent processes over a small-scale topographic\n\t\t  bump off Tasmania. The semidiurnal tide generates\n\t\t  large-amplitude transient lee waves and hydraulic jumps\n\t\t  that are unstable and dissipate the tidal energy. These\n\t\t  processes are consistent with the scattering of the\n\t\t  incident low-mode internal tide on the continental slope of\n\t\t  Tasmania. Despite elevated turbulence over the bump,\n\t\t  near-bottom energy dissipation is small relative to the\n\t\t  incident wave energy flux.},\n  copyright\t= {http://www.ametsoc.org/PUBSReuseLicenses},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/WT6YEYE8/Marques et al. -\n\t\t  2024 - Observations of Tidally Driven Turbulence over\n\t\t  Steep, Small-Scale Topography Embedded in the Tasman.pdf}\n}\n\n
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\n Abstract Enhanced diapycnal mixing induced by the near-bottom breaking of internal waves is an essential component of the lower meridional overturning circulation. Despite its crucial role in the ocean circulation, tidally driven internal wave breaking is challenging to observe due to its inherently short spatial and temporal scales. We present detailed moored and shipboard observations that resolve the spatiotemporal variability of the tidal response over a small-scale bump embedded in the continental slope of Tasmania. Cross-shore tidal currents drive a nonlinear trapped response over the steep bottom around the bump. The observations are roughly consistent with two-dimensional high-mode tidal lee-wave theory. However, the alongshore tidal velocities are large, suggesting that the alongshore bathymetric variability modulates the tidal response driven by the cross-shore tidal flow. The semidiurnal tide and energy dissipation rate are correlated at subtidal time scales, but with complex temporal variability. Energy dissipation from a simple scattering model shows that the elevated near-bottom turbulence can be sustained by the impinging mode-1 internal tide, where the dissipation over the bump is O (1%) of the incident depth-integrated energy flux. Despite this small fraction, tidal dissipation is enhanced over the bump due to steep topography at a horizontal scale of O (1) km and may locally drive significant diapycnal mixing. Significance Statement Near-bottom turbulent mixing is a key element of the global abyssal circulation. We present observations of the spatiotemporal variability of tidally driven turbulent processes over a small-scale topographic bump off Tasmania. The semidiurnal tide generates large-amplitude transient lee waves and hydraulic jumps that are unstable and dissipate the tidal energy. These processes are consistent with the scattering of the incident low-mode internal tide on the continental slope of Tasmania. Despite elevated turbulence over the bump, near-bottom energy dissipation is small relative to the incident wave energy flux.\n
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\n \n\n \n \n \n \n \n Winter Arctic Outflow Winds Cause Upper Ocean Cooling and Reoxygenation in a Temperate Canadian Fjord.\n \n \n \n\n\n \n Jackson, J. M.; Holmes, K.; Klymak, J. M.; Bianucci, L.; Evans, W.; Floyd, W. C.; Hannah, C. G.; Hare, A.; and Wan, D.\n\n\n \n\n\n\n Geophys. Res. Lett., 50(16). 2023.\n \n\n\n\n
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@Article{\t  jacksonetal23,\n  Title\t\t= {Winter Arctic Outflow Winds Cause Upper Ocean Cooling and\n\t\t  Reoxygenation in a Temperate Canadian Fjord},\n  Author\t= {Jackson, J. M. and Holmes, K. and Klymak, J. M. and\n\t\t  Bianucci, L. and Evans, W. and Floyd, W. C. and Hannah, C.\n\t\t  G. and Hare, A. and Wan, D.},\n  Year\t\t= {2023},\n  Journal\t= {Geophys. Res. Lett.},\n  Volume\t= {50},\n  Number\t= {16},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2023gl104549},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-09-28 18:45:56 -0700},\n  date-modified\t= {2024-08-12 15:11:58 -0700},\n  Keywords\t= {ButeWInds,jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/7UKJJC7T/Jackson2023.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Stratification Variability and Its Biogeochemical Implications across Queen Charlotte Sound, a Highly Productive Shelf Sea in the Northeast Pacific.\n \n \n \n\n\n \n Jhugroo, K; Waterman, e.; Jackson, e.; Klymak, e.; Ross, T; Hannah, C; and Dosser, e.\n\n\n \n\n\n\n 2023.\n Submitted \\emphJ. Geophys Res\n\n\n\n
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@Unpublished{\t  jhugrooetal23,\n  Title\t\t= {Stratification Variability and Its Biogeochemical\n\t\t  Implications across {{Queen Charlotte Sound}}, a Highly\n\t\t  Productive Shelf Sea in the {{Northeast Pacific}}},\n  Author\t= {Jhugroo, K and Waterman, {\\relax SN} and Jackson, {\\relax\n\t\t  JM} and Klymak, {\\relax JM} and Ross, T and Hannah, C and\n\t\t  Dosser, {\\relax HV}.},\n  Year\t\t= {2023},\n  date-added\t= {2023-10-29 15:22:14 -0700},\n  date-modified\t= {2023-10-29 15:25:01 -0700},\n  Keywords\t= {jmkinreview},\n  Note\t\t= {Submitted \\emph{J. Geophys Res}}\n}\n\n
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\n \n\n \n \n \n \n \n Separation of an Upwelling Current Bounding the Juan de Fuca Eddy.\n \n \n \n\n\n \n Klymak, J. M.; Allen, S. E.; and Waterman, S.\n\n\n \n\n\n\n J. Geophys. Res., 128(8). 2023.\n \n\n\n\n
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@Article{\t  klymaketal23,\n  Title\t\t= {Separation of an Upwelling Current Bounding the {{Juan}}\n\t\t  de {{Fuca Eddy}}},\n  Author\t= {Klymak, Jody M. and Allen, Susan E. and Waterman,\n\t\t  Stephanie},\n  Year\t\t= {2023},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {128},\n  Number\t= {8},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2023jc019688},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-09-19 10:04:03 -0700},\n  date-modified\t= {2023-09-19 10:05:01 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/I72TBGQ6/Klymak et al. -\n\t\t  2023 - Separation of an upwelling current bounding the Juan\n\t\t  de Fuca Eddy.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Observations of Tidally Driven Turbulence over Steep, Small-Scale Topography Embedded in the Tasman Slope.\n \n \n \n\n\n \n Marques, O. B.; Alford, M.; Pinkel, R.; MacKinnon, J.; Voet, G.; Klymak, J.; and Nash, J.\n\n\n \n\n\n\n 2023.\n in press \\emphJ.Phys.Oceanogr.\n\n\n\n
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@Unpublished{\t  marquesetal23,\n  Title\t\t= {Observations of Tidally Driven Turbulence over Steep,\n\t\t  Small-Scale Topography Embedded in the {{Tasman}} Slope},\n  Author\t= {Marques, Olavo Badaro and Alford, Matthew and Pinkel,\n\t\t  Robert and MacKinnon, Jennifer and Voet, Gunnar and Klymak,\n\t\t  Jody and Nash, Jonathan},\n  Year\t\t= {2023},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-09-29 15:15:37 -0700},\n  date-modified\t= {2023-09-29 15:17:44 -0700},\n  Keywords\t= {jmkrefereed},\n  Note\t\t= {in press \\emph{J.Phys.Oceanogr.}}\n}\n\n
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\n \n\n \n \n \n \n \n Energy and Momentum of a Density-Driven Overflow in the Samoan Passage.\n \n \n \n\n\n \n Voet, G.; Alford, M. H.; Cusack, J. M.; Pratt, L. J.; Girton, J. B.; Carter, G. S.; Klymak, J. M.; Tan, S.; and Thurnherr, A. M.\n\n\n \n\n\n\n J. Phys. Oceanogr.. 2023.\n \n\n\n\n
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@Article{\t  voetetal23,\n  Title\t\t= {Energy and Momentum of a Density-Driven Overflow in the\n\t\t  {{Samoan Passage}}},\n  Author\t= {Voet, Gunnar and Alford, Matthew H. and Cusack, Jesse M.\n\t\t  and Pratt, Larry J. and Girton, James B. and Carter, Glenn\n\t\t  S. and Klymak, Jody M. and Tan, Shuwen and Thurnherr,\n\t\t  Andreas M.},\n  Year\t\t= {2023},\n  Journal\t= {J. Phys. Oceanogr.},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-22-0220.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-04-04 17:03:36 -0700},\n  date-modified\t= {2023-09-29 15:13:20 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Spatial and Temporal Origins of the La Perouse Low Oxygen Pool: A Combined Lagrangian Statistical Approach.\n \n \n \n\n\n \n Sahu, S.; Allen, S. E.; Saldías, G. S.; Klymak, J. M.; and Zhai, L.\n\n\n \n\n\n\n J. Geophys. Res., 127(3). 2022.\n \n\n\n\n
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@Article{\t  sahuetal22,\n  Title\t\t= {Spatial and Temporal Origins of the {{La Perouse}} Low\n\t\t  Oxygen Pool: A Combined Lagrangian Statistical Approach},\n  Author\t= {Sahu, Saurav and Allen, Susan E. and Sald{\\'{\\i}}as,\n\t\t  Gonzalo S. and Klymak, Jody M. and Zhai, Li},\n  Year\t\t= {2022},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {127},\n  Number\t= {3},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2021jc018135},\n  copyright\t= {All rights reserved},\n  date-added\t= {2022-04-24 15:45:14 -0700},\n  date-modified\t= {2022-04-25 09:48:25 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,pw13}\n}\n\n
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\n \n\n \n \n \n \n \n Global Observations of Rotary-with-Depth Shear Spectra.\n \n \n \n\n\n \n Waterhouse, A. F.; Hennon, T.; Kunze, E.; MacKinnon, J. A.; Alford, M. H.; Pinkel, R.; Simmons, H.; Whalen, C. B.; Fine, E. C.; Klymak, J.; and Hummon, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr.. 2022.\n \n\n\n\n
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@Article{\t  waterhouseetal22,\n  Title\t\t= {Global Observations of Rotary-with-Depth Shear Spectra},\n  Author\t= {Waterhouse, Amy F. and Hennon, Tyler and Kunze, Eric and\n\t\t  MacKinnon, Jennifer A. and Alford, Matthew H. and Pinkel,\n\t\t  Robert and Simmons, Harper and Whalen, Caitlin B. and Fine,\n\t\t  Elizabeth C. and Klymak, Jody and Hummon, Julia M.},\n  Year\t\t= {2022},\n  Journal\t= {J. Phys. Oceanogr.},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-22-0015.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-01-15 08:23:58 -0800},\n  date-modified\t= {2023-01-15 08:25:53 -0800},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Parameterizing Non-Propagating Form Drag over Rough Bathymetry.\n \n \n \n\n\n \n Klymak, J. M.; Balwada, D.; Naveira Garabato, A. C.; and Abernathey, R.\n\n\n \n\n\n\n J. Phys. Oceanogr.. 2021.\n \n\n\n\n
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@Article{\t  klymaketal21a,\n  Title\t\t= {Parameterizing Non-Propagating Form Drag over Rough\n\t\t  Bathymetry},\n  Author\t= {Klymak, Jody M. and Balwada, Dhruv and Naveira Garabato,\n\t\t  Alberto C. and Abernathey, Ryan},\n  Year\t\t= {2021},\n  Journal\t= {J. Phys. Oceanogr.},\n  DOI\t\t= {10.1175/JPO-D-20-0112.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2021-02-16 09:47:01 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Internal Tide Structure and Temporal Variability on the Reflective Continental Slope of Southeastern Tasmania.\n \n \n \n\n\n \n Marques, O. B.; Alford, M. H.; Pinkel, R.; MacKinnon, J. A.; Klymak, J. M.; Nash, J. D.; Waterhouse, A. F.; Kelly, S. M.; Simmons, H. L.; and Braznikov, D.\n\n\n \n\n\n\n J. Phys. Oceanogr., 51(2): 611–631. 2021.\n \n\n\n\n
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@Article{\t  marquesetal21,\n  Title\t\t= {Internal Tide Structure and Temporal Variability on the\n\t\t  Reflective Continental Slope of Southeastern {{Tasmania}}},\n  Author\t= {Marques, Olavo B. and Alford, Matthew H. and Pinkel,\n\t\t  Robert and MacKinnon, Jennifer A. and Klymak, Jody M. and\n\t\t  Nash, Jonathan D. and Waterhouse, Amy F. and Kelly, Samuel\n\t\t  M. and Simmons, Harper L. and Braznikov, Dmitry},\n  Year\t\t= {2021},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {51},\n  Number\t= {2},\n  Pages\t\t= {611--631},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-20-0044.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2021-02-16 09:23:16 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n The Effect of Sea Ice on Tidal Propagation in the Kitikmeot Sea, Canadian Arctic Archipelago.\n \n \n \n\n\n \n Rotermund, L. M.; Williams, W. J.; Klymak, J. M.; Wu, Y.; Scharien, R. K.; and Haas, C.\n\n\n \n\n\n\n J. Geophys. Res., 126(5). 2021.\n \n\n\n\n
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@Article{\t  rotermunetal21,\n  Title\t\t= {The Effect of Sea Ice on Tidal Propagation in the\n\t\t  {{Kitikmeot Sea}}, {{Canadian Arctic Archipelago}}},\n  Author\t= {Rotermund, Lina M. and Williams, William J. and Klymak,\n\t\t  Jody M. and Wu, Yongsheng and Scharien, Randall K. and\n\t\t  Haas, Christian},\n  Year\t\t= {2021},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {126},\n  Number\t= {5},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2020jc016786},\n  copyright\t= {All rights reserved},\n  date-added\t= {2021-06-08 18:12:58 -0700},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Surface Drift and Dispersion in a Multiply Connected Fjord System.\n \n \n \n\n\n \n Blanken, H.; Hannah, C.; Klymak, J. M.; and Juhász, T.\n\n\n \n\n\n\n J. Geophys. Res., 125(2). 2020.\n \n\n\n\n
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@Article{\t  blankenetal20,\n  Title\t\t= {Surface Drift and Dispersion in a Multiply Connected Fjord\n\t\t  System},\n  Author\t= {Blanken, Hauke and Hannah, Charles and Klymak, Jody M. and\n\t\t  Juh{\\'a}sz, Tam{\\'a}s},\n  Year\t\t= {2020},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {125},\n  Number\t= {2},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2019jc015425},\n  copyright\t= {All rights reserved},\n  date-added\t= {2020-04-13 08:12:53 -0700},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Investigating the Formation of Submesoscale Structures along Mesoscale Fronts and Estimating Kinematic Quantities Using Lagrangian Drifters.\n \n \n \n\n\n \n Lodise, J.; Özgökmen, T.; Gon ̧calves, R. C.; Iskandarani, M.; Lund, B.; Horstmann, J.; Poulain, P.; Klymak, J.; Ryan, E. H.; and Guigand, C.\n\n\n \n\n\n\n Fluids, 5(3): 159. 2020.\n \n\n\n\n
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@Article{\t  lodise_2020,\n  Title\t\t= {Investigating the Formation of Submesoscale Structures\n\t\t  along Mesoscale Fronts and Estimating Kinematic Quantities\n\t\t  Using Lagrangian Drifters},\n  Author\t= {Lodise, John and {\\"O}zg{\\"o}kmen, Tamay and Gon{\\c\n\t\t  c}alves, Rafael C. and Iskandarani, Mohamed and Lund,\n\t\t  Bj{\\"o}rn and Horstmann, Jochen and Poulain, Pierre-Marie\n\t\t  and Klymak, Jody and Ryan, Edward H. and Guigand, Cedric},\n  Year\t\t= {2020},\n  Journal\t= {Fluids},\n  Volume\t= {5},\n  Number\t= {3},\n  Pages\t\t= {159},\n  Publisher\t= {MDPI AG},\n  DOI\t\t= {10.3390/fluids5030159},\n  copyright\t= {All rights reserved},\n  date-added\t= {2021-01-19 20:06:39 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Improved Internal Wave Spectral Continuum in a Regional Ocean Model.\n \n \n \n\n\n \n Nelson, A.; Arbic, B.; Menemenlis, D.; Peltier, W.; Alford, M.; Grisouard, N.; and Klymak, J.\n\n\n \n\n\n\n J. Geophys. Res.. 2020.\n \n\n\n\n
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@Article{\t  nelsonetal20,\n  Title\t\t= {Improved Internal Wave Spectral Continuum in a Regional\n\t\t  Ocean Model},\n  Author\t= {Nelson, A.D. and Arbic, B.K. and Menemenlis, D. and\n\t\t  Peltier, W.R. and Alford, M.H. and Grisouard, N. and\n\t\t  Klymak, J.M.},\n  Year\t\t= {2020},\n  Journal\t= {J. Geophys. Res.},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2019jc015974},\n  copyright\t= {All rights reserved},\n  date-added\t= {2020-04-20 08:43:54 -0700},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Observations of Cross-Frontal Exchange Associated with Submesoscale Features along the North Wall of the Gulf Stream.\n \n \n \n\n\n \n Sanchez-Rios, A.; Shearman, R. K.; Klymak, J.; DAsaro, E.; and Lee, C.\n\n\n \n\n\n\n Deep Sea Res. Part Oceanogr. Res. Pap., 163: 103342. 2020.\n \n\n\n\n
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@Article{\t  sanchez_rios_2020,\n  Title\t\t= {Observations of Cross-Frontal Exchange Associated with\n\t\t  Submesoscale Features along the {{North Wall}} of the\n\t\t  {{Gulf Stream}}},\n  Author\t= {{Sanchez-Rios}, Alejandra and Shearman, R. Kipp and\n\t\t  Klymak, Jody and DAsaro, Eric and Lee, Craig},\n  Year\t\t= {2020},\n  Journal\t= {Deep Sea Res. Part Oceanogr. Res. Pap.},\n  Volume\t= {163},\n  Pages\t\t= {103342},\n  Publisher\t= {Elsevier BV},\n  DOI\t\t= {10.1016/j.dsr.2020.103342},\n  copyright\t= {All rights reserved},\n  date-added\t= {2021-01-19 20:07:10 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Data Availability Principles and Practice.\n \n \n \n\n\n \n Smith, J. A.; Cessi, P.; Fer, I.; Foltz, G.; Fox-Kemper, B.; Heywood, K.; Jones, N.; Klymak, J.; and LaCasce, J.\n\n\n \n\n\n\n J. Phys. Oceanogr., 50(12): 3377–3378. 2020.\n \n\n\n\n
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@Article{\t  smithetal20,\n  Title\t\t= {Data Availability Principles and Practice},\n  Author\t= {Smith, Jerome A. and Cessi, Paola and Fer, Ilker and\n\t\t  Foltz, Gregory and {Fox-Kemper}, Baylor and Heywood, Karen\n\t\t  and Jones, Nicole and Klymak, Jody and LaCasce, Joseph},\n  Year\t\t= {2020},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {50},\n  Number\t= {12},\n  Pages\t\t= {3377--3378},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-20-0266.1},\n  date-added\t= {2021-02-16 09:25:20 -0800},\n  date-modified\t= {2022-01-14 11:31:49 +0100},\n  jmkpubtype\t= {other},\n  Keywords\t= {jmkother}\n}\n\n
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\n \n\n \n \n \n \n \n Enhanced Mixing across the Gyre Boundary at the Gulf Stream Front.\n \n \n \n\n\n \n Wenegrat, J. O.; Thomas, L. N.; Sundermeyer, M. A.; Taylor, J. R.; D'Asaro, E. A.; Klymak, J. M.; Shearman, R. K.; and Lee, C. M.\n\n\n \n\n\n\n Proc. Natl. Acad. Sci., 117(30): 17607–17614. 2020.\n \n\n\n\n
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@Article{\t  wenegrat_2020,\n  Title\t\t= {Enhanced Mixing across the Gyre Boundary at the {{Gulf\n\t\t  Stream}} Front},\n  Author\t= {Wenegrat, Jacob O. and Thomas, Leif N. and Sundermeyer,\n\t\t  Miles A. and Taylor, John R. and D'Asaro, Eric A. and\n\t\t  Klymak, Jody M. and Shearman, R. Kipp and Lee, Craig M.},\n  Year\t\t= {2020},\n  Journal\t= {Proc. Natl. Acad. Sci.},\n  Volume\t= {117},\n  Number\t= {30},\n  Pages\t\t= {17607--17614},\n  Publisher\t= {Proceedings of the National Academy of Sciences},\n  DOI\t\t= {10.1073/pnas.2005558117},\n  copyright\t= {All rights reserved},\n  date-added\t= {2021-01-19 20:05:58 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Internal Wave-Driven Mixing: Governing Processes and Consequences for Climate.\n \n \n \n\n\n \n Whalen, C. B.; de Lavergne , C.; Garabato, A. C. N.; Klymak, J. M.; MacKinnon, J. A.; and Sheen, K. L.\n\n\n \n\n\n\n Nat. Rev. Earth Environ., 1(11): 606–621. 2020.\n \n\n\n\n
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@Article{\t  whalen_2020,\n  Title\t\t= {Internal Wave-Driven Mixing: Governing Processes and\n\t\t  Consequences for Climate},\n  Author\t= {Whalen, Caitlin B. and {de Lavergne}, Casimir and\n\t\t  Garabato, Alberto C. Naveira and Klymak, Jody M. and\n\t\t  MacKinnon, Jennifer A. and Sheen, Katy L.},\n  Year\t\t= {2020},\n  Journal\t= {Nat. Rev. Earth Environ.},\n  Volume\t= {1},\n  Number\t= {11},\n  Pages\t\t= {606--621},\n  Publisher\t= {{Springer Science and Business Media LLC}},\n  DOI\t\t= {10.1038/s43017-020-0097-z},\n  copyright\t= {All rights reserved},\n  date-added\t= {2021-01-19 20:05:19 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n  \n 2019\n \n \n (9)\n \n \n
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\n \n\n \n \n \n \n \n Connecting Process Models of Topographic Wave Drag to Global Eddying General Circulation Models.\n \n \n \n\n\n \n Arbic, B.; Fringer, O.; Klymak, J.; Mayer, F.; Trossman, D.; and Zhu, P.\n\n\n \n\n\n\n Oceanography, 32(4): 146–155. 2019.\n \n\n\n\n
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@Article{\t  arbicetal19,\n  Title\t\t= {Connecting Process Models of Topographic Wave Drag to\n\t\t  Global Eddying General Circulation Models},\n  Author\t= {Arbic, Brian and Fringer, Oliver and Klymak, Jody and\n\t\t  Mayer, Frederick and Trossman, David and Zhu, Peiyun},\n  Year\t\t= {2019},\n  Journal\t= {Oceanography},\n  Volume\t= {32},\n  Number\t= {4},\n  Pages\t\t= {146--155},\n  Publisher\t= {The Oceanography Society},\n  DOI\t\t= {10.5670/oceanog.2019.420},\n  copyright\t= {All rights reserved},\n  date-added\t= {2020-04-13 08:30:48 -0700},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Better Regional Ocean Observing through Cross-National Cooperation: A Case Study from the Northeast Pacific.\n \n \n \n\n\n \n Barth, J. A.; Allen, S. E.; Dever, E. P.; Dewey, R. K.; Evans, W.; Feely, R. A.; Fisher, J. L.; Fram, J. P.; Hales, B.; Ianson, D.; Jackson, J.; Juniper, K.; Kawka, O.; Kelley, D.; Klymak, J. M.; Konovsky, J.; Kosro, P. M.; Kurapov, A.; Mayorga, E.; MacCready, P.; Newton, J.; Perry, R. I.; Risien, C. M.; Robert, M.; Ross, T.; Shearman, R. K.; Schumacker, J.; Siedlecki, S.; Trainer, V. L.; Waterman, S.; and Wingard, C. E.\n\n\n \n\n\n\n Front. Mar. Sci., 6. 2019.\n \n\n\n\n
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@Article{\t  barthetal19,\n  Title\t\t= {Better Regional Ocean Observing through Cross-National\n\t\t  Cooperation: A Case Study from the Northeast Pacific},\n  Author\t= {Barth, John A. and Allen, Susan E. and Dever, Edward P.\n\t\t  and Dewey, Richard K. and Evans, Wiley and Feely, Richard\n\t\t  A. and Fisher, Jennifer L. and Fram, Jonathan P. and Hales,\n\t\t  Burke and Ianson, Debby and Jackson, Jennifer and Juniper,\n\t\t  Kim and Kawka, Orest and Kelley, Deborah and Klymak, Jody\n\t\t  M. and Konovsky, John and Kosro, P. Michael and Kurapov,\n\t\t  Alexander and Mayorga, Emilio and MacCready, Parker and\n\t\t  Newton, Jan and Perry, R. Ian and Risien, Craig M. and\n\t\t  Robert, Marie and Ross, Tetjana and Shearman, R. Kipp and\n\t\t  Schumacker, Joe and Siedlecki, Samantha and Trainer, Vera\n\t\t  L. and Waterman, Stephanie and Wingard, Christopher E.},\n  Year\t\t= {2019},\n  Journal\t= {Front. Mar. Sci.},\n  Volume\t= {6},\n  Publisher\t= {Frontiers Media SA},\n  DOI\t\t= {10.3389/fmars.2019.00093},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-10-29 10:34:19 -0700},\n  date-modified\t= {2023-10-29 10:34:19 -0700},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n A Spatial Geography of Abyssal Turbulent Mixing in the Samoan Passage.\n \n \n \n\n\n \n Carter, G.; Voet, G.; Alford, M.; Girton, J.; Mickett, J.; Klymak, J.; Pratt, L.; Pearson-Potts, K.; Cusack, J.; and al. , e.\n\n\n \n\n\n\n Oceanography, 32(4): 194–203. 2019.\n \n\n\n\n
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@Article{\t  carteretal19,\n  Title\t\t= {A Spatial Geography of Abyssal Turbulent Mixing in the\n\t\t  {{Samoan Passage}}},\n  Author\t= {Carter, Glenn and Voet, Gunnar and Alford, Matthew and\n\t\t  Girton, James and Mickett, John and Klymak, Jody and Pratt,\n\t\t  Larry and {Pearson-Potts}, Kelly and Cusack, Jesse and\n\t\t  {al.}, et},\n  Year\t\t= {2019},\n  Journal\t= {Oceanography},\n  Volume\t= {32},\n  Number\t= {4},\n  Pages\t\t= {194--203},\n  Publisher\t= {The Oceanography Society},\n  DOI\t\t= {10.5670/oceanog.2019.425},\n  copyright\t= {All rights reserved},\n  date-added\t= {2019-12-20 12:04:40 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Flow-Topography Interactions in the Samoan Passage.\n \n \n \n\n\n \n Girton, J.; Mickett, undefined; John; Zhao, Z.; Alford, M.; Voet, G.; Cusack, J.; Carter, G.; Pearson-Potts, K.; Pratt, L.; Tan, S.; and Klymak, J.\n\n\n \n\n\n\n Oceanography, 32(4): 184–193. 2019.\n \n\n\n\n
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@Article{\t  girtonetal19,\n  Title\t\t= {Flow-Topography Interactions in the Samoan Passage},\n  Author\t= {Girton, James and Mickett, {and} John and Zhao, ZhongXiang\n\t\t  and Alford, Matthew and Voet, Gunnar and Cusack, Jesse and\n\t\t  Carter, Glenn and {Pearson-Potts}, Kelly and Pratt, Larry\n\t\t  and Tan, Shuwen and Klymak, Jody},\n  Year\t\t= {2019},\n  Journal\t= {Oceanography},\n  Volume\t= {32},\n  Number\t= {4},\n  Pages\t\t= {184--193},\n  Publisher\t= {The Oceanography Society},\n  DOI\t\t= {10.5670/oceanog.2019.424},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-10-29 10:38:25 -0700},\n  date-modified\t= {2023-10-29 10:38:25 -0700},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Tidal Conversion and Dissipation at Steep Topography in a Channel Poleward of the Critical Latitude.\n \n \n \n\n\n \n Hughes, K. G.; and Klymak, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr., 49(5): 1269–1291. 2019.\n \n\n\n\n
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@Article{\t  hughesklymak19,\n  Title\t\t= {Tidal Conversion and Dissipation at Steep Topography in a\n\t\t  Channel Poleward of the Critical Latitude},\n  Author\t= {Hughes, Kenneth G. and Klymak, Jody M.},\n  Year\t\t= {2019},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {49},\n  Number\t= {5},\n  Pages\t\t= {1269--1291},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-18-0132.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2019-09-15 10:05:02 -0700},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n The Variability of Winds and Fluxes Observed near Submesoscale Fronts.\n \n \n \n\n\n \n Shao, M.; Ortiz-Suslow, D. G.; Haus, B. K.; Lund, B.; Williams, N. J.; Özgökmen, T. M.; Laxague, N. J. M.; Horstmann, J.; and Klymak, J. M.\n\n\n \n\n\n\n J. Geophys. Res.. 2019.\n \n\n\n\n
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@Article{\t  shaoetal19,\n  Title\t\t= {The Variability of Winds and Fluxes Observed near\n\t\t  Submesoscale Fronts},\n  Author\t= {Shao, Mingming and Ortiz-Suslow, David G. and Haus, Brian\n\t\t  K. and Lund, Bjorn and Williams, Neil J. and\n\t\t  {\\"O}zg{\\"o}kmen, Tamay M. and Laxague, Nathan J. M. and\n\t\t  Horstmann, Jochen and Klymak, Jody M.},\n  Year\t\t= {2019},\n  Journal\t= {J. Geophys. Res.},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2019jc015236},\n  copyright\t= {All rights reserved},\n  date-added\t= {2019-12-20 12:06:02 -0800},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Recent Progress in Modeling Imbalance in the Atmosphere and Ocean.\n \n \n \n\n\n \n Sutherland, B. R.; Achatz, U.; Caulfield, C. P.; and Klymak, J. M.\n\n\n \n\n\n\n Phys. Rev. Fluids, 4(1). 2019.\n \n\n\n\n
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@Article{\t  sutherlandetal19,\n  Title\t\t= {Recent Progress in Modeling Imbalance in the Atmosphere\n\t\t  and Ocean},\n  Author\t= {Sutherland, Bruce R. and Achatz, Ulrich and Caulfield,\n\t\t  Colm-cille P. and Klymak, Jody M.},\n  Year\t\t= {2019},\n  Journal\t= {Phys. Rev. Fluids},\n  Volume\t= {4},\n  Number\t= {1},\n  Publisher\t= {American Physical Society (APS)},\n  DOI\t\t= {10.1103/physrevfluids.4.010501},\n  copyright\t= {All rights reserved},\n  date-added\t= {2019-09-15 10:04:25 -0700},\n  date-modified\t= {2021-06-10 16:49:30 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n OceanGliders: A Component of the Integrated GOOS.\n \n \n \n\n\n \n Testor, P.; de Young , B.; Rudnick, D. L.; Glenn, S.; Hayes, D.; Lee, C. M.; Pattiaratchi, C.; Hill, K.; Heslop, E.; Turpin, V.; Alenius, P.; Barrera, C.; Barth, J. A.; Beaird, N.; Bécu, G.; Bosse, A.; Bourrin, F.; Brearley, J. A.; Chao, Y.; Chen, S.; Chiggiato, J.; Coppola, L.; Crout, R.; Cummings, J.; Curry, B.; Curry, R.; Davis, R.; Desai, K.; DiMarco, S.; Edwards, C.; Fielding, S.; Fer, I.; Frajka-Williams, E.; Gildor, H.; Goni, G.; Gutierrez, D.; Haugan, P.; Hebert, D.; Heiderich, J.; Henson, S.; Heywood, K.; Hogan, P.; Houpert, L.; Huh, S.; Inall, M. E.; Ishii, M.; Ito, S.; Itoh, S.; Jan, S.; Kaiser, J.; Karstensen, J.; Kirkpatrick, B.; Klymak, J.; Kohut, J.; Krahmann, G.; Krug, M.; McClatchie, S.; Marin, F.; Mauri, E.; Mehra, A.; Meredith, M. P.; Meunier, T.; Miles, T.; Morell, J. M.; Mortier, L.; Nicholson, S.; OCallaghan, J.; OConchubhair, D.; Oke, P.; Pallàs-Sanz, E.; Palmer, M.; Park, J.; Perivoliotis, L.; Poulain, P.; Perry, R.; Queste, B.; Rainville, L.; Rehm, E.; Roughan, M.; Rome, N.; Ross, T.; Ruiz, S.; Saba, G.; Schaeffer, A.; Schönau, M.; Schroeder, K.; Shimizu, Y.; Sloyan, B. M.; Smeed, D.; Snowden, D.; Song, Y.; Swart, S.; Tenreiro, M.; Thompson, A.; Tintore, J.; Todd, R. E.; Toro, C.; Venables, H.; Wagawa, T.; Waterman, S.; Watlington, R. A.; and Wilson, D.\n\n\n \n\n\n\n Front. Mar. Sci., 6. 2019.\n \n\n\n\n
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@Article{\t  testoretal19,\n  Title\t\t= {{{OceanGliders}}: A Component of the Integrated {{GOOS}}},\n  Author\t= {Testor, Pierre and {de Young}, Brad and Rudnick, Daniel L.\n\t\t  and Glenn, Scott and Hayes, Daniel and Lee, Craig M. and\n\t\t  Pattiaratchi, Charitha and Hill, Katherine and Heslop, Emma\n\t\t  and Turpin, Victor and Alenius, Pekka and Barrera, Carlos\n\t\t  and Barth, John A. and Beaird, Nicholas and B{\\'e}cu,\n\t\t  Guislain and Bosse, Anthony and Bourrin, Fran{\\c c}ois and\n\t\t  Brearley, J. Alexander and Chao, Yi and Chen, Sue and\n\t\t  Chiggiato, Jacopo and Coppola, Laurent and Crout, Richard\n\t\t  and Cummings, James and Curry, Beth and Curry, Ruth and\n\t\t  Davis, Richard and Desai, Kruti and DiMarco, Steve and\n\t\t  Edwards, Catherine and Fielding, Sophie and Fer, Ilker and\n\t\t  {Frajka-Williams}, Eleanor and Gildor, Hezi and Goni,\n\t\t  Gustavo and Gutierrez, Dimitri and Haugan, Peter and\n\t\t  Hebert, David and Heiderich, Joleen and Henson, Stephanie\n\t\t  and Heywood, Karen and Hogan, Patrick and Houpert,\n\t\t  Lo{\\"{\\i}}c and Huh, Sik and Inall, Mark E. and Ishii,\n\t\t  Masso and Ito, Shin-ichi and Itoh, Sachihiko and Jan, Sen\n\t\t  and Kaiser, Jan and Karstensen, Johannes and Kirkpatrick,\n\t\t  Barbara and Klymak, Jody and Kohut, Josh and Krahmann, Gerd\n\t\t  and Krug, Marjolaine and McClatchie, Sam and Marin,\n\t\t  Fr{\\'e}d{\\'e}ric and Mauri, Elena and Mehra, Avichal and\n\t\t  Meredith, Michael P. and Meunier, Thomas and Miles, Travis\n\t\t  and Morell, Julio M. and Mortier, Laurent and Nicholson,\n\t\t  Sarah and OCallaghan, Joanne and OConchubhair, Diarmuid and\n\t\t  Oke, Peter and {Pall{\\`a}s-Sanz}, Enric and Palmer, Matthew\n\t\t  and Park, JongJin and Perivoliotis, Leonidas and Poulain,\n\t\t  Pierre-Marie and Perry, Ruth and Queste, Bastien and\n\t\t  Rainville, Luc and Rehm, Eric and Roughan, Moninya and\n\t\t  Rome, Nicholas and Ross, Tetjana and Ruiz, Simon and Saba,\n\t\t  Grace and Schaeffer, Amandine and Sch{\\"o}nau, Martha and\n\t\t  Schroeder, Katrin and Shimizu, Yugo and Sloyan, Bernadette\n\t\t  M. and Smeed, David and Snowden, Derrick and Song, Yumi and\n\t\t  Swart, Sebastian and Tenreiro, Miguel and Thompson, Andrew\n\t\t  and Tintore, Joaquin and Todd, Robert E. and Toro, Cesar\n\t\t  and Venables, Hugh and Wagawa, Taku and Waterman, Stephanie\n\t\t  and Watlington, Roy A. and Wilson, Doug},\n  Year\t\t= {2019},\n  Journal\t= {Front. Mar. Sci.},\n  Volume\t= {6},\n  Publisher\t= {Frontiers Media SA},\n  DOI\t\t= {10.3389/fmars.2019.00422},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-10-29 10:35:45 -0700},\n  date-modified\t= {2023-10-29 10:35:45 -0700},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Geodesy and Geophysics in Canada 2015-2019.\n \n \n \n\n\n \n Young, G.; Woo, J.; Fotopoulos, G.; McCausland, P.; Themens, D.; Petrone, R.; Ali, G.; Kushnet, P.; Merlis, T.; Klymak, J.; Galbraith, P.; Darbyshire, F.; Molnar, S.; Williams-Jones, G.; Vigoroux, N.; Kelly, R.; and Scarien, R.\n\n\n \n\n\n\n Technical Report Canadian National Committee for the International Union of Geodesy and Geophysics, 2019.\n \n\n\n\n
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@TechReport{\t  youngetal19,\n  Title\t\t= {Geodesy and Geophysics in {{Canada}} 2015-2019},\n  Author\t= {Young, Gordon and Woo, Jeong and Fotopoulos, Georgia and\n\t\t  McCausland, Phil and Themens, David and Petrone, Richard\n\t\t  and Ali, Genevieve and Kushnet, Paul and Merlis, Time and\n\t\t  Klymak, Jody and Galbraith, Peter and Darbyshire, Fiona and\n\t\t  Molnar, Sheri and {Williams-Jones}, Glyn and Vigoroux,\n\t\t  Nathalie and Kelly, Richard and Scarien, Randy},\n  Year\t\t= {2019},\n  Institution\t= {{Canadian National Committee for the International Union\n\t\t  of Geodesy and Geophysics}},\n  date-added\t= {2020-04-17 07:47:51 -0700},\n  date-modified\t= {2021-06-10 16:45:50 -0700},\n  jmkpubtype\t= {other},\n  Keywords\t= {jmkother}\n}\n
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\n  \n 2018\n \n \n (4)\n \n \n
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\n \n\n \n \n \n \n \n Ocean Convergence and the Dispersion of Flotsam.\n \n \n \n\n\n \n D'Asaro, E. A.; Shcherbina, A. Y.; Klymak, J. M.; Molemaker, J.; Novelli, G.; Guigand, C. M.; Haza, A. C.; Haus, B. K.; Ryan, E. H.; Jacobs, G. A.; Huntley, H. S.; Laxague, N. J. M.; Chen, S.; Judt, F.; McWilliams, J. C.; Barkan, R.; Jr., A. D. K.; Poje, A. C.; and Özgökmen, T. M.\n\n\n \n\n\n\n Proc. Natl. Acad. Sci. U.S.A,201718453. 2018.\n \n\n\n\n
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@Article{\t  dasaroetal18,\n  Title\t\t= {Ocean Convergence and the Dispersion of Flotsam},\n  Author\t= {D'Asaro, Eric A. and Shcherbina, Andrey Y. and Klymak,\n\t\t  Jody M. and Molemaker, Jeroen and Novelli, Guillaume and\n\t\t  Guigand, C{\\'e}dric M. and Haza, Angelique C. and Haus,\n\t\t  Brian K. and Ryan, Edward H. and Jacobs, Gregg A. and\n\t\t  Huntley, Helga S. and Laxague, Nathan J. M. and Chen, Shuyi\n\t\t  and Judt, Falko and McWilliams, James C. and Barkan, Roy\n\t\t  and Jr., A. D. Kirwan and Poje, Andrew C. and\n\t\t  {\\"O}zg{\\"o}kmen, Tamay M.},\n  Year\t\t= {2018},\n  Journal\t= {Proc. Natl. Acad. Sci. U.S.A},\n  Pages\t\t= {201718453},\n  Publisher\t= {Proceedings of the National Academy of Sciences},\n  DOI\t\t= {10.1073/pnas.1718453115},\n  copyright\t= {All rights reserved},\n  date-added\t= {2018-01-29 22:18:34 +0000},\n  date-modified\t= {2021-06-10 19:03:22 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Tidally Modulated Internal Hydraulic Flow and Energetics in the Central Canadian Arctic Archipelago.\n \n \n \n\n\n \n Hughes, K. G.; Klymak, J. M.; Williams, W. J.; and Melling, H.\n\n\n \n\n\n\n J. Geophys. Res.. 2018.\n \n\n\n\n
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@Article{\t  hughesetal18,\n  Title\t\t= {Tidally Modulated Internal Hydraulic Flow and Energetics\n\t\t  in the Central {{Canadian Arctic Archipelago}}},\n  Author\t= {Hughes, Kenneth G. and Klymak, Jody M. and Williams,\n\t\t  William J. and Melling, Humfrey},\n  Year\t\t= {2018},\n  Journal\t= {J. Geophys. Res.},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2018jc013770},\n  copyright\t= {All rights reserved},\n  date-added\t= {2018-06-20 17:33:21 +0000},\n  date-modified\t= {2021-06-10 16:45:24 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/LAGK2U83/Hughes et al. -\n\t\t  2018 - Tidally modulated internal hydraulic flow and\n\t\t  energetics in the central Canadian Arctic Archipelago.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Nonpropagating Form Drag and Turbulence Due to Stratified Flow over Large-Scale Abyssal Hill Topography.\n \n \n \n\n\n \n Klymak, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr., 48(10): 2383–2395. 2018.\n \n\n\n\n
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@Article{\t  klymak18,\n  Title\t\t= {Nonpropagating Form Drag and Turbulence Due to Stratified\n\t\t  Flow over Large-Scale Abyssal Hill Topography},\n  Author\t= {Klymak, Jody M.},\n  Year\t\t= {2018},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {48},\n  Number\t= {10},\n  Pages\t\t= {2383--2395},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-17-0225.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2019-07-26 15:33:30 -0700},\n  date-modified\t= {2021-06-10 16:45:37 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Interaction of Superinertial Waves with Submesoscale Cyclonic Filaments in the North Wall of the Gulf Stream.\n \n \n \n\n\n \n Whitt, D. B.; Thomas, L. N.; Klymak, J. M.; Lee, C. M.; and D'Asaro, E. A.\n\n\n \n\n\n\n J. Phys. Oceanogr., 48(1): 81–99. 2018.\n \n\n\n\n
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@Article{\t  whittetal2018,\n  Title\t\t= {Interaction of Superinertial Waves with Submesoscale\n\t\t  Cyclonic Filaments in the North Wall of the {{Gulf\n\t\t  Stream}}},\n  Author\t= {Whitt, Daniel B. and Thomas, Leif N. and Klymak, Jody M.\n\t\t  and Lee, Craig M. and D'Asaro, Eric A.},\n  Year\t\t= {2018},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {48},\n  Number\t= {1},\n  Pages\t\t= {81--99},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-17-0079.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2018-01-29 22:17:09 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Space–Time Scales of Shear in the North Pacific.\n \n \n \n\n\n \n Alford, M. H.; MacKinnon, J. A.; Pinkel, R.; and Klymak, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr., 47(10): 2455–2478. 2017.\n \n\n\n\n
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@Article{\t  alfordetal17,\n  Title\t\t= {Space--Time Scales of Shear in the {{North Pacific}}},\n  Author\t= {Alford, Matthew H. and MacKinnon, Jennifer A. and Pinkel,\n\t\t  Robert and Klymak, Jody M.},\n  Year\t\t= {2017},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {47},\n  Number\t= {10},\n  Pages\t\t= {2455--2478},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-17-0087.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2018-01-29 22:15:53 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Water Mass Modification and Mixing Rates in a 1/12\\,\\textsuperscript$∘$ Simulation of the Canadian Arctic Archipelago.\n \n \n \n\n\n \n Hughes, K. G.; Klymak, J. M.; Hu, X.; and Myers, P. G.\n\n\n \n\n\n\n J. Geophys. Res., 122(2): 803–820. 2017.\n \n\n\n\n
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@Article{\t  hughesetal17,\n  Title\t\t= {Water Mass Modification and Mixing Rates in a\n\t\t  1/12\\,{\\textsuperscript{{$\\circ$}}} Simulation of the\n\t\t  {{Canadian Arctic Archipelago}}},\n  Author\t= {Hughes, Kenneth G. and Klymak, Jody M. and Hu, Xianmin and\n\t\t  Myers, Paul G.},\n  Year\t\t= {2017},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {122},\n  Number\t= {2},\n  Pages\t\t= {803--820},\n  Publisher\t= {Wiley-Blackwell},\n  DOI\t\t= {10.1002/2016jc012235},\n  copyright\t= {All rights reserved},\n  date-added\t= {2017-04-27 00:04:58 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Climate Process Team on Internal Wave–Driven Ocean Mixing.\n \n \n \n\n\n \n MacKinnon, J. A.; Zhao, Z.; Whalen, C. B.; Waterhouse, A. F.; Trossman, D. S.; Sun, O. M.; Laurent, L. C. S.; Simmons, H. L.; Polzin, K.; Pinkel, R.; Pickering, A.; Norton, N. J.; Nash, J. D.; Musgrave, R.; Merchant, L. M.; Melet, A. V.; Mater, B.; Legg, S.; Large, W. G.; Kunze, E.; Klymak, J. M.; Jochum, M.; Jayne, S. R.; Hallberg, R. W.; Griffies, S. M.; Diggs, S.; Danabasoglu, G.; Chassignet, E. P.; Buijsman, M. C.; Bryan, F. O.; Briegleb, B. P.; Barna, A.; Arbic, B. K.; Ansong, J. K.; and Alford, M. H.\n\n\n \n\n\n\n Bull. Am. Meteorol. Soc., 98(11): 2429–2454. 2017.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  mackinnonetal17,\n  Title\t\t= {Climate Process Team on Internal Wave--Driven Ocean\n\t\t  Mixing},\n  Author\t= {MacKinnon, Jennifer A. and Zhao, Zhongxiang and Whalen,\n\t\t  Caitlin B. and Waterhouse, Amy F. and Trossman, David S.\n\t\t  and Sun, Oliver M. and Laurent, Louis C. St. and Simmons,\n\t\t  Harper L. and Polzin, Kurt and Pinkel, Robert and\n\t\t  Pickering, Andrew and Norton, Nancy J. and Nash, Jonathan\n\t\t  D. and Musgrave, Ruth and Merchant, Lynne M. and Melet,\n\t\t  Angelique V. and Mater, Benjamin and Legg, Sonya and Large,\n\t\t  William G. and Kunze, Eric and Klymak, Jody M. and Jochum,\n\t\t  Markus and Jayne, Steven R. and Hallberg, Robert W. and\n\t\t  Griffies, Stephen M. and Diggs, Steve and Danabasoglu,\n\t\t  Gokhan and Chassignet, Eric P. and Buijsman, Maarten C. and\n\t\t  Bryan, Frank O. and Briegleb, Bruce P. and Barna, Andrew\n\t\t  and Arbic, Brian K. and Ansong, Joseph K. and Alford,\n\t\t  Matthew H.},\n  Year\t\t= {2017},\n  Journal\t= {Bull. Am. Meteorol. Soc.},\n  Volume\t= {98},\n  Number\t= {11},\n  Pages\t\t= {2429--2454},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/bams-d-16-0030.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2023-10-29 10:44:24 -0700},\n  date-modified\t= {2023-10-29 10:44:24 -0700},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Submesoscale Streamers Exchange Water on the North Wall of the Gulf Stream.\n \n \n \n\n\n \n Klymak, J. M; Shearman, R K.; Gula, J.; Lee, C. M; D'Asaro, E. A; Thomas, L. N; Harcourt, R. R; Shcherbina, A. Y; Sundermeyer, M. A; Molemaker, J.; and others\n\n\n \n\n\n\n Geophys. Res. Lett.. 2016.\n \n\n\n\n
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@Article{\t  klymaketal16,\n  Title\t\t= {Submesoscale Streamers Exchange Water on the North Wall of\n\t\t  the {{Gulf Stream}}},\n  Author\t= {Klymak, Jody M and Shearman, R Kipp and Gula, Jonathan and\n\t\t  Lee, Craig M and D'Asaro, Eric A and Thomas, Leif N and\n\t\t  Harcourt, Ramsey R and Shcherbina, Andrey Y and\n\t\t  Sundermeyer, Miles A and Molemaker, Jeroen and others},\n  Year\t\t= {2016},\n  Journal\t= {Geophys. Res. Lett.},\n  Publisher\t= {Wiley Online Library},\n  DOI\t\t= {10.1002/2015GL067152},\n  copyright\t= {All rights reserved},\n  date-added\t= {2016-02-05 18:19:05 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Reflection of Linear Internal Tides from Realistic Topography: The Tasman Continental Slope.\n \n \n \n\n\n \n Klymak, J. M.; Simmons, H. L.; Braznikov, D.; Kelly, S.; MacKinnon, J. A.; Alford, M. H.; Pinkel, R.; and Nash, J. D.\n\n\n \n\n\n\n J. Phys. Oceanogr.. 2016.\n \n\n\n\n
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@Article{\t  klymaketal16b,\n  Title\t\t= {Reflection of Linear Internal Tides from Realistic\n\t\t  Topography: {{The Tasman}} Continental Slope},\n  Author\t= {Klymak, Jody M. and Simmons, Harper L. and Braznikov,\n\t\t  Dmitry and Kelly, Samuel and MacKinnon, Jennifer A. and\n\t\t  Alford, Matthew H. and Pinkel, Robert and Nash, Jonathan\n\t\t  D.},\n  Year\t\t= {2016},\n  Journal\t= {J. Phys. Oceanogr.},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-16-0061.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2016-10-12 23:12:59 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Symmetric Instability, Inertial Oscillations, and Turbulence at the Gulf Stream Front.\n \n \n \n\n\n \n Thomas, L. N; Taylor, J. R; D'Asaro, E. A; Lee, C. M; Klymak, J. M; and Shcherbina, A.\n\n\n \n\n\n\n J. Phys. Oceanogr., 46(1): 197–217. 2016.\n \n\n\n\n
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@Article{\t  thomasetal16,\n  Title\t\t= {Symmetric Instability, Inertial Oscillations, and\n\t\t  Turbulence at the {{Gulf Stream}} Front},\n  Author\t= {Thomas, Leif N and Taylor, John R and D'Asaro, Eric A and\n\t\t  Lee, Craig M and Klymak, Jody M and Shcherbina, Andrey},\n  Year\t\t= {2016},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {46},\n  Number\t= {1},\n  Pages\t\t= {197--217},\n  DOI\t\t= {10.1175/JPO-D-15-0008.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2016-02-05 18:21:23 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Warming and Weakening of the Abyssal Flow through Samoan Passage.\n \n \n \n\n\n \n Voet, G.; Alford, M. H.; Girton, J. B.; Carter, G. S.; Mickett, J. B.; and Klymak, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr., 46(8): 2389–2401. 2016.\n \n\n\n\n
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@Article{\t  voetetal16a,\n  Title\t\t= {Warming and Weakening of the Abyssal Flow through {{Samoan\n\t\t  Passage}}},\n  Author\t= {Voet, Gunnar and Alford, Matthew H. and Girton, James B.\n\t\t  and Carter, Glenn S. and Mickett, John B. and Klymak, Jody\n\t\t  M.},\n  Year\t\t= {2016},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {46},\n  Number\t= {8},\n  Pages\t\t= {2389--2401},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/jpo-d-16-0063.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2016-10-12 23:14:02 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n  \n 2015\n \n \n (10)\n \n \n
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\n \n\n \n \n \n \n \n The Formation and Fate of Internal Waves in the South China Sea.\n \n \n \n\n\n \n Alford, M. H.; Peacock, T.; MacKinnon, J. A.; Nash, J. D.; Buijsman, M. C.; Centuroni, L. R.; Chao, S.; Chang, M.; Farmer, D. M.; Fringer, O. B.; Fu, K.; Gallacher, P. C.; Graber, H. C.; Helfrich, K. R.; Jachec, S. M.; Jackson, C. R.; Klymak, J. M.; Ko, D. S.; Jan, S.; Johnston, T. M. S.; Legg, S.; Lee, I.; Lien, R.; Mercier, M. J.; Moum, J. N.; Musgrave, R.; Park, J.; Pickering, A. I.; Pinkel, R.; Rainville, L.; Ramp, S. R.; Rudnick, D. L.; Sarkar, S.; Scotti, A.; Simmons, H. L.; St Laurent, L. C.; Venayagamoorthy, S. K.; Wang, Y.; Wang, J.; Yang, Y. J.; Paluszkiewicz, T.; and (David) Tang, T.\n\n\n \n\n\n\n Nature, 521(7550): 65–69. 2015.\n \n\n\n\n
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@Article{\t  alfordetal15a,\n  Title\t\t= {The Formation and Fate of Internal Waves in the {{South\n\t\t  China Sea}}},\n  Author\t= {Alford, Matthew H. and Peacock, Thomas and MacKinnon,\n\t\t  Jennifer A. and Nash, Jonathan D. and Buijsman, Maarten C.\n\t\t  and Centuroni, Luca R. and Chao, Shenn-Yu and Chang,\n\t\t  Ming-Huei and Farmer, David M. and Fringer, Oliver B. and\n\t\t  Fu, Ke-Hsien and Gallacher, Patrick C. and Graber, Hans C.\n\t\t  and Helfrich, Karl R. and Jachec, Steven M. and Jackson,\n\t\t  Christopher R. and Klymak, Jody M. and Ko, Dong S. and Jan,\n\t\t  Sen and Johnston, T. M. Shaun and Legg, Sonya and Lee,\n\t\t  I-Huan and Lien, Ren-Chieh and Mercier, Matthieu J. and\n\t\t  Moum, James N. and Musgrave, Ruth and Park, Jae-Hun and\n\t\t  Pickering, Andrew I. and Pinkel, Robert and Rainville, Luc\n\t\t  and Ramp, Steven R. and Rudnick, Daniel L. and Sarkar,\n\t\t  Sutanu and Scotti, Alberto and Simmons, Harper L. and St\n\t\t  Laurent, Louis C. and Venayagamoorthy, Subhas K. and Wang,\n\t\t  Yu-Huai and Wang, Joe and Yang, Yiing J. and Paluszkiewicz,\n\t\t  Theresa and (David) Tang, Tswen-Yung},\n  Year\t\t= {2015},\n  Journal\t= {Nature},\n  Volume\t= {521},\n  Number\t= {7550},\n  Pages\t\t= {65--69},\n  Publisher\t= {Nature Publishing Group, a division of Macmillan\n\t\t  Publishers Limited. All Rights Reserved.},\n  DOI\t\t= {10.1038/nature14399},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-05-11 20:55:20 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  ISBN\t\t= {0028-0836},\n  jmkpubtype\t= {refereed},\n  l3\t\t= {10.1038/nature14399},\n  m3\t\t= {Letter},\n  ty\t\t= {JOUR},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/BS9YTUCY/Alfordetal15aa.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Outside Influences on the Water Column of Cumberland Sound, Baffin Island.\n \n \n \n\n\n \n Bedard, J. M; Vagle, S.; Klymak, J. M; Williams, W. J; Curry, B.; and Lee, C. M\n\n\n \n\n\n\n J. Geophys. Res., 120(7): 5000–5018. 2015.\n \n\n\n\n
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@Article{\t  bedardetal15b,\n  Title\t\t= {Outside Influences on the Water Column of Cumberland\n\t\t  Sound, Baffin Island},\n  Author\t= {Bedard, Jeannette M and Vagle, Svein and Klymak, Jody M\n\t\t  and Williams, William J and Curry, Beth and Lee, Craig M},\n  Year\t\t= {2015},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {120},\n  Number\t= {7},\n  Pages\t\t= {5000--5018},\n  Publisher\t= {Wiley Online Library},\n  DOI\t\t= {10.1002/2015JC010811},\n  copyright\t= {All rights reserved},\n  date-added\t= {2016-02-05 18:26:56 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/EBT8KN8E/bedard2015outsidea.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Seasonality in Submesoscale Turbulence.\n \n \n \n\n\n \n Callies, J.; Ferrari, R.; Klymak, J. M; and Gula, J.\n\n\n \n\n\n\n Nat.Commun., 6. 2015.\n \n\n\n\n
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@Article{\t  calliesetal15,\n  Title\t\t= {Seasonality in Submesoscale Turbulence},\n  Author\t= {Callies, J{\\"o}rn and Ferrari, Raffaele and Klymak, Jody M\n\t\t  and Gula, Jonathan},\n  Year\t\t= {2015},\n  Journal\t= {Nat.Commun.},\n  Volume\t= {6},\n  Publisher\t= {Nature Publishing Group},\n  DOI\t\t= {10.1038/ncomms7862},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-05-20 03:52:56 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/CLSKLHMT/Callies et al. -\n\t\t  2015 - Seasonality in submesoscale turbulence.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Dissipation of Internal Wave Energy Generated on a Critical Slope.\n \n \n \n\n\n \n Gemmrich, J.; and Klymak, J. M\n\n\n \n\n\n\n J. Phys. Oceanogr., 45: 2221—2238. 2015.\n \n\n\n\n
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@Article{\t  gemmrichklymak15,\n  Title\t\t= {Dissipation of Internal Wave Energy Generated on a\n\t\t  Critical Slope},\n  Author\t= {Gemmrich, Johannes and Klymak, Jody M},\n  Year\t\t= {2015},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {45},\n  Pages\t\t= {2221---2238},\n  DOI\t\t= {10.1175/JPO-D-14-0236.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-05-20 03:52:10 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n In Situ O$_2$ and N$_2$ Measurements Detect Deep-Water Renewal Dynamics in Seasonally-Anoxic Saanich Inlet.\n \n \n \n\n\n \n Hamme, R. C; Berry, J. E; Klymak, J. M; and Denman, K. L\n\n\n \n\n\n\n Cont. Shelf Res., 106: 107–117. 2015.\n \n\n\n\n
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@Article{\t  hammeetal15,\n  Title\t\t= {In Situ {{O}}{$_2$} and {{N}}{$_2$} Measurements Detect\n\t\t  Deep-Water Renewal Dynamics in Seasonally-Anoxic {{Saanich\n\t\t  Inlet}}},\n  Author\t= {Hamme, Roberta C and Berry, Johanna E and Klymak, Jody M\n\t\t  and Denman, Kenneth L},\n  Year\t\t= {2015},\n  Journal\t= {Cont. Shelf Res.},\n  Volume\t= {106},\n  Pages\t\t= {107--117},\n  Publisher\t= {Elsevier},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-10-16 21:02:05 +0000},\n  date-modified\t= {2023-10-25 14:20:06 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/ZZ4UM2UK/hammeetal15a.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Along-Isopycnal Variability of Spice in the North Pacific.\n \n \n \n\n\n \n Klymak, J. M.; Crawford, W.; Alford, M. H.; MacKinnon, J. A.; and Pinkel, R.\n\n\n \n\n\n\n J. Geophys. Res.,2169–9291. 2015.\n \n\n\n\n
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@Article{\t  klymaketal15a,\n  Title\t\t= {Along-Isopycnal Variability of Spice in the {{North\n\t\t  Pacific}}},\n  Author\t= {Klymak, Jody M. and Crawford, William and Alford, Matthew\n\t\t  H. and MacKinnon, Jennifer A. and Pinkel, Robert},\n  Year\t\t= {2015},\n  Journal\t= {J. Geophys. Res.},\n  Pages\t\t= {2169--9291},\n  DOI\t\t= {10.1002/2013JC009421},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-03-04 19:28:57 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,lateral mixing,ocean turbulence,submesoscale\n\t\t  dynamics,upper ocean dynamics},\n  File\t\t= {/Users/jklymak/Zotero/storage/5BC2XEC6/klymaketal15aa.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Submesoscale Water Mass Spectra in the Sargasso Sea.\n \n \n \n\n\n \n Kunze, E; Klymak, e.; Lien, R.; Ferrari, R; Lee, e.; Sundermeyer, e.; and Goodman, L\n\n\n \n\n\n\n J. Phys. Oceanogr., 45. 2015.\n \n\n\n\n
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@Article{\t  kunzeetal15,\n  Title\t\t= {Submesoscale Water Mass Spectra in the {{Sargasso Sea}}},\n  Author\t= {Kunze, E and Klymak, {\\relax JM} and Lien, R-C and\n\t\t  Ferrari, R and Lee, {\\relax CM} and Sundermeyer, {\\relax\n\t\t  MA} and Goodman, L},\n  Year\t\t= {2015},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {45},\n  DOI\t\t= {10.1175/JPO-D-14-0108.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-05-20 03:53:32 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/3TVFXS6T/kunzeetal15a.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Breaking Internal Tides Keep the Ocean in Balance.\n \n \n \n\n\n \n Pinkel, R.; Alford, M.; Lucas, A.; Johnston, S.; MacKinnon, J.; Waterhouse, A.; Jones, N.; Kelly, S.; Klymak, J.; Nash, J.; and al. , e.\n\n\n \n\n\n\n Eos, 96. 2015.\n \n\n\n\n
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@Article{\t  pinkeletal15,\n  Title\t\t= {Breaking Internal Tides Keep the Ocean in Balance},\n  Author\t= {Pinkel, Robert and Alford, Matthew and Lucas, Andrew and\n\t\t  Johnston, Shaun and MacKinnon, Jennifer and Waterhouse, Amy\n\t\t  and Jones, Nicole and Kelly, Sam and Klymak, Jody and Nash,\n\t\t  Jonathan and {al.}, et},\n  Year\t\t= {2015},\n  Journal\t= {Eos},\n  Volume\t= {96},\n  Publisher\t= {American Geophysical Union (AGU)},\n  DOI\t\t= {10.1029/2015eo039555},\n  copyright\t= {All rights reserved},\n  date-added\t= {2020-04-17 08:00:00 -0700},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Pathways, Volume Transport and Mixing of Abyssal Water in the Samoan Passage.\n \n \n \n\n\n \n Voet, G.; Girton, J. B; Alford, M. H; Carter, G. S; Klymak, J. M; and Mickett, J. B\n\n\n \n\n\n\n J. Phys. Oceanogr., 45: 562–588. 2015.\n \n\n\n\n
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@Article{\t  voetetal15,\n  Title\t\t= {Pathways, Volume Transport and Mixing of Abyssal Water in\n\t\t  the {{Samoan Passage}}},\n  Author\t= {Voet, Gunnar and Girton, James B and Alford, Matthew H and\n\t\t  Carter, Glenn S and Klymak, Jody M and Mickett, John B},\n  Year\t\t= {2015},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {45},\n  Pages\t\t= {562--588},\n  DOI\t\t= {10.1175/JPO-D-14-0096.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-01-28 16:45:37 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/4ZJXWVWL/voetetal14a.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Barotropic Tidal Dynamics in a Frictional Subsidiary Channel.\n \n \n \n\n\n \n Wan, D.; Klymak, J. M.; Foreman, M. G.; and Cross, S. F.\n\n\n \n\n\n\n Cont. Shelf Res.. 2015.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n  \n \n abstract \n \n\n \n  \n \n 2 downloads\n \n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n \n \n\n\n\n
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@Article{\t  wanetal15,\n  Title\t\t= {Barotropic Tidal Dynamics in a Frictional Subsidiary\n\t\t  Channel},\n  Author\t= {Wan, Di and Klymak, Jody M. and Foreman, Michael G.G. and\n\t\t  Cross, Stephen F.},\n  Year\t\t= {2015},\n  Journal\t= {Cont. Shelf Res.},\n  DOI\t\t= {10.1016/j.csr.2015.05.011},\n  Abstract\t= {Abstract Barotropic M 2 tidal dynamics are studied in a\n\t\t  subsidiary tidal channel in Kyuquot Sound, Canada, a site\n\t\t  proposed for multi-trophic aquaculture. A regional model\n\t\t  with no stratification or forcing other than the tide found\n\t\t  that the sea level in the subsidiary channel responded in\n\t\t  phase with the rest of Kyuquot Sound, but that the velocity\n\t\t  response was almost 180\\,\\textsuperscript{{$\\circ$}} out of\n\t\t  phase. Further, this velocity difference was strongly\n\t\t  dependent on the choice of viscous parameterization in the\n\t\t  model. A simple linear analytical model was developed to\n\t\t  explain the simulated changes in terms of the phase lag\n\t\t  induced by viscosity, and allowed a larger parameter regime\n\t\t  to be explored. These results suggest that verifying models\n\t\t  of smaller channels using sea level measurements alone is\n\t\t  inadequate, and velocity measurements are necessary.},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-06-05 18:10:40 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {Energy dissipation,jmkrefereed}\n}\n\n
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\n Abstract Barotropic M 2 tidal dynamics are studied in a subsidiary tidal channel in Kyuquot Sound, Canada, a site proposed for multi-trophic aquaculture. A regional model with no stratification or forcing other than the tide found that the sea level in the subsidiary channel responded in phase with the rest of Kyuquot Sound, but that the velocity response was almost 180\\,\\textsuperscript$∘$ out of phase. Further, this velocity difference was strongly dependent on the choice of viscous parameterization in the model. A simple linear analytical model was developed to explain the simulated changes in terms of the phase lag induced by viscosity, and allowed a larger parameter regime to be explored. These results suggest that verifying models of smaller channels using sea level measurements alone is inadequate, and velocity measurements are necessary.\n
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\n \n\n \n \n \n \n \n Breaking Internal Lee Waves at Kaena Ridge, Hawaii.\n \n \n \n\n\n \n Alford, M. H; Klymak, J. M; and Carter, G. S\n\n\n \n\n\n\n Geophys. Res. Lett.. 2014.\n \n\n\n\n
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@Article{\t  alfordetal14,\n  Title\t\t= {Breaking Internal Lee Waves at {{Kaena Ridge}},\n\t\t  {{Hawaii}}},\n  Author\t= {Alford, Matthew H and Klymak, Jody M and Carter, Glenn S},\n  Year\t\t= {2014},\n  Journal\t= {Geophys. Res. Lett.},\n  DOI\t\t= {10.1002/2013GL059070},\n  copyright\t= {All rights reserved},\n  date-added\t= {2014-01-25 21:42:34 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/8ASVR9WF/alfordetal14a.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Three-Dimensional Double-Ridge Internal Tide Resonance in Luzon Strait.\n \n \n \n\n\n \n Buijsman, M. C; Klymak, J. M; Legg, S.; Alford, M. H; Farmer, D.; MacKinnon, J. A; Nash, J. D; Park, J.; Pickering, A.; and Simmons, H.\n\n\n \n\n\n\n J. Phys. Oceanogr., 44(3): 850–869. 2014.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  buijsmanetal14,\n  Title\t\t= {Three-Dimensional Double-Ridge Internal Tide Resonance in\n\t\t  {{Luzon Strait}}},\n  Author\t= {Buijsman, Maarten C and Klymak, Jody M and Legg, Sonya and\n\t\t  Alford, Matthew H and Farmer, David and MacKinnon, Jennifer\n\t\t  A and Nash, Jonathan D and Park, Jae-Hun and Pickering,\n\t\t  Andy and Simmons, Harper},\n  Year\t\t= {2014},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {44},\n  Number\t= {3},\n  Pages\t\t= {850--869},\n  DOI\t\t= {10.1175/JPO-D-13-024.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-01-28 16:42:10 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Mode-2 Hydraulic Control of Flow over a Small Ridge on a Continental Shelf.\n \n \n \n\n\n \n Gregg, e.; and Klymak, J. M\n\n\n \n\n\n\n J. Geophys. Res., 119(11): 8093–8108. 2014.\n \n\n\n\n
\n\n\n\n \n\n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  greggklymak14,\n  Title\t\t= {Mode-2 Hydraulic Control of Flow over a Small Ridge on a\n\t\t  Continental Shelf},\n  Author\t= {Gregg, {\\relax MC} and Klymak, Jody M},\n  Year\t\t= {2014},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {119},\n  Number\t= {11},\n  Pages\t\t= {8093--8108},\n  Publisher\t= {Wiley Online Library},\n  copyright\t= {All rights reserved},\n  date-added\t= {2015-01-28 16:39:03 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/KNBRY7DH/gregg2014modea.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Turbulence and Internal Waves in Patricia Bay, Saanich Inlet, British Columbia.\n \n \n \n\n\n \n Sato, M; Klymak, e.; Kunze, E; Dewey, R; and Dower, e.\n\n\n \n\n\n\n Cont. Shelf Res., 85: 153–167. 2014.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  satoetal14,\n  Title\t\t= {Turbulence and Internal Waves in {{Patricia Bay}},\n\t\t  {{Saanich Inlet}}, {{British Columbia}}},\n  Author\t= {Sato, M and Klymak, {\\relax JM} and Kunze, E and Dewey, R\n\t\t  and Dower, {\\relax JF}},\n  Year\t\t= {2014},\n  Journal\t= {Cont. Shelf Res.},\n  Volume\t= {85},\n  Pages\t\t= {153--167},\n  Publisher\t= {Elsevier},\n  DOI\t\t= {10.1016/j.csr.2014.06.009},\n  copyright\t= {All rights reserved},\n  date-added\t= {2014-08-25 17:42:01 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/VHT5TRK2/satoetal14a.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Observations of the Internal Tide on the California Continental Margin near Monterey Bay.\n \n \n \n\n\n \n Terker, S. R; Girton, J. B; Kunze, E.; Klymak, J. M; and Pinkel, R.\n\n\n \n\n\n\n Cont. Shelf Res., 82: 60–71. 2014.\n \n\n\n\n
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@Article{\t  terkeretal14,\n  Title\t\t= {Observations of the Internal Tide on the {{California}}\n\t\t  Continental Margin near {{Monterey Bay}}},\n  Author\t= {Terker, Samantha R and Girton, James B and Kunze, Eric and\n\t\t  Klymak, Jody M and Pinkel, Robert},\n  Year\t\t= {2014},\n  Journal\t= {Cont. Shelf Res.},\n  Volume\t= {82},\n  Pages\t\t= {60--71},\n  Publisher\t= {Elsevier},\n  copyright\t= {All rights reserved},\n  date-added\t= {2014-08-25 17:43:42 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/4EG6I9EJ/terkeretal14a.pdf}\n}\n\n
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\n  \n 2013\n \n \n (7)\n \n \n
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\n \n\n \n \n \n \n \n Turbulent Mixing and Hydraulic Control of Abyssal Water in the Samoan Passage.\n \n \n \n\n\n \n Alford, e.; Girton, J. B; Voet, G.; Carter, G. S; Mickett, J. B; and Klymak, J. M\n\n\n \n\n\n\n Geophys. Res. Lett.. 2013.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  alfordetal13,\n  Title\t\t= {Turbulent Mixing and Hydraulic Control of Abyssal Water in\n\t\t  the {{Samoan Passage}}},\n  Author\t= {Alford, {\\relax MH} and Girton, James B and Voet, Gunnar\n\t\t  and Carter, Glenn S and Mickett, John B and Klymak, Jody M},\n  Year\t\t= {2013},\n  Journal\t= {Geophys. Res. Lett.},\n  Publisher\t= {Wiley Online Library},\n  DOI\t\t= {10.1002/grl.50684},\n  copyright\t= {All rights reserved},\n  date-added\t= {2013-09-09 20:22:29 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {Hydraulics,jmkrefereed,Observations,Samoan Passage}\n}\n\n
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\n \n\n \n \n \n \n \n Estimating Oceanic Turbulence Dissipation from Seismic Images.\n \n \n \n\n\n \n Holbrook, W S.; Fer, I.; Schmitt, R. W; Lizarralde, D.; Klymak, J. M; Helfrich, L C.; and Kubichek, R.\n\n\n \n\n\n\n J. Atmos. Ocean. Tech., 30(8). 2013.\n \n\n\n\n
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@Article{\t  holbrooketal13,\n  Title\t\t= {Estimating Oceanic Turbulence Dissipation from Seismic\n\t\t  Images.},\n  Author\t= {Holbrook, W Steven and Fer, Ilker and Schmitt, Raymond W\n\t\t  and Lizarralde, Daniel and Klymak, Jody M and Helfrich, L\n\t\t  Cody and Kubichek, Robert},\n  Year\t\t= {2013},\n  Journal\t= {J. Atmos. Ocean. Tech.},\n  Volume\t= {30},\n  Number\t= {8},\n  copyright\t= {All rights reserved},\n  date-added\t= {2014-01-25 21:42:34 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Parameterizing Baroclinic Internal Tide Scattering and Breaking on Supercritical Topography: The One- and Two-Ridge Cases.\n \n \n \n\n\n \n Klymak, J. M.; Buijsman, M.; Legg, S. M.; and Pinkel, R.\n\n\n \n\n\n\n J. Phys. Oceanogr., 43: 1380–1397. 2013.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  klymaketal13a,\n  Title\t\t= {Parameterizing Baroclinic Internal Tide Scattering and\n\t\t  Breaking on Supercritical Topography: The One- and\n\t\t  Two-Ridge Cases},\n  Author\t= {Klymak, Jody M. and Buijsman, Maarten and Legg, Sonya M.\n\t\t  and Pinkel, Robert},\n  Year\t\t= {2013},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {43},\n  Pages\t\t= {1380--1397},\n  DOI\t\t= {http://dx.doi.org/10.1175/JPO-D-12-061.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2014-01-25 21:40:43 +0000},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {Internal Tide,jmkrefereed,Modelling,turbulence}\n}\n\n
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\n \n\n \n \n \n \n \n The Latitudinal Dependence of Shear and Mixing in the Pacific Transiting the Critical Latitude for PSI.\n \n \n \n\n\n \n MacKinnon, e.; Alford, e.; Pinkel, R.; Klymak, J.; and Zhao, Z.\n\n\n \n\n\n\n J. Phys. Oceanogr., 43(1): 3–16. 2013.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  mackinnonetal13a,\n  Title\t\t= {The Latitudinal Dependence of Shear and Mixing in the\n\t\t  {{Pacific}} Transiting the Critical Latitude for {{PSI}}},\n  Author\t= {MacKinnon, {\\relax JA} and Alford, {\\relax MH} and Pinkel,\n\t\t  Rob and Klymak, Jody and Zhao, Zhongxiang},\n  Year\t\t= {2013},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {43},\n  Number\t= {1},\n  Pages\t\t= {3--16},\n  DOI\t\t= {10.1175/JPO-D-11-0107.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2013-09-11 23:12:31 +0000},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {Hawaii,jmkrefereed,Observations,PSI}\n}\n\n
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\n \n\n \n \n \n \n \n Parametric Subharmonic Instability of the Internal Tide at 29 N.\n \n \n \n\n\n \n MacKinnon, e.; Alford, M. H; Sun, O.; Pinkel, R.; Zhao, Z.; and Klymak, J.\n\n\n \n\n\n\n J. Phys. Oceanogr., 43(1): 17–28. 2013.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  mackinnonetal13b,\n  Title\t\t= {Parametric Subharmonic Instability of the Internal Tide at\n\t\t  29 {{N}}},\n  Author\t= {MacKinnon, {\\relax JA} and Alford, Matthew H and Sun,\n\t\t  Oliver and Pinkel, Rob and Zhao, Zhongxiang and Klymak,\n\t\t  Jody},\n  Year\t\t= {2013},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {43},\n  Number\t= {1},\n  Pages\t\t= {17--28},\n  DOI\t\t= {10.1175/JPO-D-11-0108.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2013-09-11 23:14:59 +0000},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {Hawaii,jmkrefereed,Observations,PSI}\n}\n\n
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\n \n\n \n \n \n \n \n Near-Inertial Waves Observed during the Internal Waves Across the Pacific Experiment.\n \n \n \n\n\n \n Pickering, A.; Alford, M.; Zhao, Z.; MacKinnon, J.; Pinkel, R.; and Klymak, J.\n\n\n \n\n\n\n 2013.\n in prep.\n\n\n\n
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@Unpublished{\t  pickeringetal13,\n  Title\t\t= {Near-Inertial Waves Observed during the {{Internal Waves\n\t\t  Across}} the {{Pacific}} Experiment},\n  Author\t= {Pickering, Andrew and Alford, Matthew and Zhao, Zhongxiang\n\t\t  and MacKinnon, Jennifer and Pinkel, Rob and Klymak, Jody},\n  Year\t\t= {2013},\n  copyright\t= {All rights reserved},\n  date-added\t= {2011-08-18 16:06:49 -0700},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  Keywords\t= {jmkrefereed},\n  Note\t\t= {in prep.}\n}\n\n
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\n \n\n \n \n \n \n \n Statistics of Vertical Vorticity, Divergence, and Strain in a Developed Submesoscale Turbulence Field.\n \n \n \n\n\n \n Shcherbina, A. Y; D'Asaro, E. A; Lee, C. M; Klymak, J. M; Molemaker, M J.; and McWilliams, J. C\n\n\n \n\n\n\n Geophys. Res. Lett., 40(17): 4706–4711. 2013.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  shcherbinaetal13,\n  Title\t\t= {Statistics of Vertical Vorticity, Divergence, and Strain\n\t\t  in a Developed Submesoscale Turbulence Field},\n  Author\t= {Shcherbina, Andrey Y and D'Asaro, Eric A and Lee, Craig M\n\t\t  and Klymak, Jody M and Molemaker, M Jeroen and McWilliams,\n\t\t  James C},\n  Year\t\t= {2013},\n  Journal\t= {Geophys. Res. Lett.},\n  Volume\t= {40},\n  Number\t= {17},\n  Pages\t\t= {4706--4711},\n  DOI\t\t= {10.1002/grl.50919},\n  copyright\t= {All rights reserved},\n  date-added\t= {2014-01-25 21:42:34 +0000},\n  date-modified\t= {2021-06-10 16:44:52 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n  \n 2012\n \n \n (5)\n \n \n
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\n \n\n \n \n \n \n \n Annual Cycle and Depth Penetration of Wind-Generated near-Inertial Internal Waves at Ocean Station Papa in the Sub-Arctic Pacific.\n \n \n \n\n\n \n Alford, M. H.; Cronin, M.; and Klymak, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr. 2012.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  alfordetal11b,\n  Title\t\t= {Annual Cycle and Depth Penetration of Wind-Generated\n\t\t  near-Inertial Internal Waves at {{Ocean Station Papa}} in\n\t\t  the Sub-{{Arctic Pacific}}},\n  Author\t= {Alford, Matthew H. and Cronin, Meghan and Klymak, Jody\n\t\t  M.},\n  Year\t\t= {2012},\n  Journal\t= {J. Phys. Oceanogr},\n  DOI\t\t= {10.1175/JPO-D-11-092.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2011-05-22 16:53:05 -0700},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,LineP,Near Inertial Waves,Observations},\n  File\t\t= {/Users/jklymak/Zotero/storage/MI2GNXFD/alfordetal11ba.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Double-Ridge Internal Tide Interference and Its Effect on Dissipation in Luzon Strait.\n \n \n \n\n\n \n Buijsman, M. C.; Legg, S.; and Klymak, J.\n\n\n \n\n\n\n J. Phys. Oceanogr., 42(8): 1337–1356. 2012.\n doi: 10.1175/JPO-D-11-0210.1\n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  buijsmanetal12,\n  Title\t\t= {Double-Ridge Internal Tide Interference and Its Effect on\n\t\t  Dissipation in Luzon Strait},\n  Author\t= {Buijsman, Maarten C. and Legg, Sonya and Klymak, Jody},\n  Year\t\t= {2012},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {42},\n  Number\t= {8},\n  Pages\t\t= {1337--1356},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/JPO-D-11-0210.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2013-02-27 22:52:45 +0000},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  ISBN\t\t= {0022-3670},\n  jmkpubtype\t= {refereed},\n  journal1\t= {J. Phys. Oceanogr.},\n  Keywords\t= {jmkrefereed,Modelling,NLIWI,South China Sea,Turbulence},\n  Note\t\t= {doi: 10.1175/JPO-D-11-0210.1}\n}\n\n
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\n \n\n \n \n \n \n \n The Direct Breaking of Internal Waves at Steep Topography.\n \n \n \n\n\n \n Klymak, J. M.; Buijsman, M.; Legg, S. M.; and Pinkel, R.\n\n\n \n\n\n\n Oceanography, 25(2): 150–159. 2012.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  klymaketal12b,\n  Title\t\t= {The Direct Breaking of Internal Waves at Steep\n\t\t  Topography},\n  Author\t= {Klymak, Jody M. and Buijsman, Maarten and Legg, Sonya M.\n\t\t  and Pinkel, Robert},\n  Year\t\t= {2012},\n  Journal\t= {Oceanography},\n  Volume\t= {25},\n  Number\t= {2},\n  Pages\t\t= {150--159},\n  DOI\t\t= {10.5670/oceanog.2012.50},\n  copyright\t= {All rights reserved},\n  date-added\t= {2012-03-23 23:21:06 +0000},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {Internal Tides,jmkrefereed,Modelling,Turbulence},\n  File\t\t= {/Users/jklymak/Zotero/storage/L3SSFJKD/klymaketal12ba.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Breaking Topographic Lee Waves in a Tidal Channel in Luzon Strait.\n \n \n \n\n\n \n Pinkel, R.; Buijsman, M.; and Klymak, J.\n\n\n \n\n\n\n Oceanography, 25(2): 160. 2012.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  pinkel2012breaking,\n  Title\t\t= {Breaking Topographic Lee Waves in a Tidal Channel in\n\t\t  {{Luzon Strait}}},\n  Author\t= {Pinkel, R. and Buijsman, M. and Klymak, J.M.},\n  Year\t\t= {2012},\n  Journal\t= {Oceanography},\n  Volume\t= {25},\n  Number\t= {2},\n  Pages\t\t= {160},\n  DOI\t\t= {10.5670/oceanog.2012.51},\n  copyright\t= {All rights reserved},\n  date-added\t= {2012-10-30 22:00:32 +0000},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,NLIWI,Observations,South China Sea}\n}\n\n
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\n \n\n \n \n \n \n \n Semidiurnal Baroclinic Wave Momentum Fluxes at Kaena Ridge, Hawaii.\n \n \n \n\n\n \n Pinkel, R.; Rainville, L.; and Klymak, J.\n\n\n \n\n\n\n J. Phys. Oceanogr, 42(8): 1249–1269. 2012.\n doi: 10.1175/JPO-D-11-0124.1\n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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 
@Article{\t  pinkeletal12,\n  Title\t\t= {Semidiurnal Baroclinic Wave Momentum Fluxes at {{Kaena\n\t\t  Ridge}}, {{Hawaii}}},\n  Author\t= {Pinkel, Robert and Rainville, Luc and Klymak, Jody},\n  Year\t\t= {2012},\n  Journal\t= {J. Phys. Oceanogr},\n  Volume\t= {42},\n  Number\t= {8},\n  Pages\t\t= {1249--1269},\n  Publisher\t= {American Meteorological Society},\n  DOI\t\t= {10.1175/JPO-D-11-0124.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2012-10-30 21:58:47 +0000},\n  date-modified\t= {2021-06-10 16:44:28 -0700},\n  ISBN\t\t= {0022-3670},\n  jmkpubtype\t= {refereed},\n  journal1\t= {J. Phys. Oceanogr.},\n  m3\t\t= {doi: 10.1175/JPO-D-11-0124.1},\n  ty\t\t= {JOUR},\n  year1\t\t= {2012},\n  Keywords\t= {Hawaii,Internal Tide,jmkrefereed,Observations},\n  Note\t\t= {doi: 10.1175/JPO-D-11-0124.1}\n}\n\n
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\n  \n 2011\n \n \n (4)\n \n \n
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\n \n\n \n \n \n \n \n Energy Flux and Dissipation in Luzon Strait: Two Tales of Two Ridges.\n \n \n \n\n\n \n Alford, M. H.; MacKinnon, J. A.; Nash, J. D.; Simmons, H.; Pickering, A.; Klymak, J. M.; Pinkel, R.; Sun, O.; Rainville, L.; Musgrave, R.; Beitzel, T.; Fu, K.; and Lu, C.\n\n\n \n\n\n\n J. Phys. Oceanogr, 41(11): 2211–2222. 2011.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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 
@Article{\t  alfordetal11a,\n  Title\t\t= {Energy Flux and Dissipation in {{Luzon Strait}}: Two Tales\n\t\t  of Two Ridges},\n  Author\t= {Alford, Matthew H. and MacKinnon, Jennifer A. and Nash,\n\t\t  Jonathan D. and Simmons, Harper and Pickering, Andy and\n\t\t  Klymak, Jody M. and Pinkel, Robert and Sun, Oliver and\n\t\t  Rainville, Luc and Musgrave, Ruth and Beitzel, Tamara and\n\t\t  Fu, Ke-Hsien and Lu, Chung-Wei},\n  Year\t\t= {2011},\n  Journal\t= {J. Phys. Oceanogr},\n  Volume\t= {41},\n  Number\t= {11},\n  Pages\t\t= {2211--2222},\n  DOI\t\t= {10.1175/JPO-D-11-073.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2011-05-22 16:49:50 -0700},\n  date-modified\t= {2021-06-10 16:43:50 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,Modelling,NLIWI,Observations,South China Sea}\n}\n\n
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\n \n\n \n \n \n \n \n Tidal Generation of Large Sub-Mesoscale Eddy Dipoles.\n \n \n \n\n\n \n Callendar, W.; Klymak, J. M.; and Foreman, M. G. G.\n\n\n \n\n\n\n Ocean Sci., 7(4): 487–502. 2011.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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 
@Article{\t  callendaretal11,\n  Title\t\t= {Tidal Generation of Large Sub-Mesoscale Eddy Dipoles},\n  Author\t= {Callendar, W. and Klymak, J. M. and Foreman, M. G. G.},\n  Year\t\t= {2011},\n  Journal\t= {Ocean Sci.},\n  Volume\t= {7},\n  Number\t= {4},\n  Pages\t\t= {487--502},\n  DOI\t\t= {10.5194/os-7-487-2011},\n  copyright\t= {All rights reserved},\n  date-added\t= {2011-08-03 05:52:36 -0700},\n  date-modified\t= {2021-06-10 16:43:50 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,Modelling,Student,Vorticity}\n}\n\n
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\n \n\n \n \n \n \n \n Physical Oceanography in Canada, 2007-2010: A Review for the International Association for the Physical Sciences of the Oceans.\n \n \n \n\n\n \n Greenan, B.; and Klymak, J. M.\n\n\n \n\n\n\n Technical Report U. of Victoria, 2011.\n \n\n\n\n
\n\n\n\n \n\n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@TechReport{\t  greenklymak11,\n  Title\t\t= {Physical {{Oceanography}} in {{Canada}}, 2007-2010: {{A\n\t\t  Review}} for the {{International Association}} for the\n\t\t  {{Physical Sciences}} of the {{Oceans}}},\n  Author\t= {Greenan, Blair and Klymak, Jody M.},\n  Year\t\t= {2011},\n  Institution\t= {U. of Victoria},\n  date-added\t= {2013-06-01 21:02:46 +0000},\n  date-modified\t= {2021-06-10 16:43:54 -0700},\n  jmkpubtype\t= {other},\n  Keywords\t= {jmkother},\n  File\t\t= {/Users/jklymak/Zotero/storage/97DRKPNP/GreenKlymak11a}\n}\n\n
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\n \n\n \n \n \n \n \n The Breaking and Scattering of the Internal Tide on a Continental Slope.\n \n \n \n\n\n \n Klymak, J.; Alford, M.; Pinkel, R.; Lien, R.; Yang, Y.; and Tang, T.\n\n\n \n\n\n\n J. Phys. Oceanogr, 41: 926–945. 2011.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  klymaketal11a,\n  Title\t\t= {The Breaking and Scattering of the Internal Tide on a\n\t\t  Continental Slope},\n  Author\t= {Klymak, J.M. and Alford, M.H. and Pinkel, R. and Lien,\n\t\t  R.C. and Yang, Y.J. and Tang, T.Y.},\n  Year\t\t= {2011},\n  Journal\t= {J. Phys. Oceanogr},\n  Volume\t= {41},\n  Pages\t\t= {926--945},\n  DOI\t\t= {10.1175/2010JPO4500.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2011-08-02 10:06:17 -0700},\n  date-modified\t= {2021-06-10 16:43:50 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {Internal Tide,jmkrefereed,NLIWI,Observations,South China\n\t\t  Sea,Turbulence},\n  File\t\t= {/Users/jklymak/Zotero/storage/QYJHCVS7/klymaketal11aa.pdf}\n}\n\n
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\n  \n 2010\n \n \n (4)\n \n \n
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\n \n\n \n \n \n \n \n Speed and Evolution of Nonlinear Internal Waves Transiting the South China Sea.\n \n \n \n\n\n \n Alford, M.; Lien, R.; Simmons, H.; Klymak, J.; Ramp, S.; Yang, Y.; Tang, D.; and M.H.-Chang\n\n\n \n\n\n\n J. Phys. Oceanogr., 40(6): 1338–1355. 2010.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  alfordetal10,\n  Title\t\t= {Speed and Evolution of Nonlinear Internal Waves Transiting\n\t\t  the {{South China Sea}}},\n  Author\t= {Alford, M.H. and Lien, R.-C. and Simmons, H. and Klymak,\n\t\t  J.M. and Ramp, S. and Yang, Y. and Tang, D. and\n\t\t  {M.H.-Chang}},\n  Year\t\t= {2010},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {40},\n  Number\t= {6},\n  Pages\t\t= {1338--1355},\n  DOI\t\t= {10.1175/2010JPO4388.1},\n  copyright\t= {All rights reserved},\n  date-added\t= {2010-01-11 17:22:19 -0800},\n  date-modified\t= {2022-01-14 11:47:47 +0100},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,NLIWI,observations,solitary waves,South China\n\t\t  Sea}\n}\n\n
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\n \n\n \n \n \n \n \n High-Mode Stationary Waves in Stratified Flow over Large Obstacles.\n \n \n \n\n\n \n Klymak, J. M.; Legg, S.; and Pinkel, R.\n\n\n \n\n\n\n J. Fluid Mech., 644: 312–336. 2010.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  klymaketal10a,\n  Title\t\t= {High-Mode Stationary Waves in Stratified Flow over Large\n\t\t  Obstacles},\n  Author\t= {Klymak, Jody M. and Legg, Sonya and Pinkel, Robert},\n  Year\t\t= {2010},\n  Journal\t= {J. Fluid Mech.},\n  Volume\t= {644},\n  Pages\t\t= {312--336},\n  DOI\t\t= {10.1017/S0022112009992503},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:50 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/3ZB65SFN/klymaketal10aa.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n A Simple Parameterization of Turbulent Tidal Mixing near Supercritical Topography.\n \n \n \n\n\n \n Klymak, J. M.; Legg, S.; and Pinkel, R.\n\n\n \n\n\n\n J. Phys. Oceanogr., 40(9): 2059–2074. 2010.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  klymaketal10b,\n  Title\t\t= {A Simple Parameterization of Turbulent Tidal Mixing near\n\t\t  Supercritical Topography},\n  Author\t= {Klymak, Jody M. and Legg, Sonya and Pinkel, Robert},\n  Year\t\t= {2010},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {40},\n  Number\t= {9},\n  EPrint\t= {http://journals.ametsoc.org/doi/pdf/10.1175/2010JPO4396.1},\n  Pages\t\t= {2059--2074},\n  DOI\t\t= {10.1175/2010JPO4396.1},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:50 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n A Simple Mixing Scheme for Models That Resolve Breaking Internal Waves.\n \n \n \n\n\n \n Klymak, J. M.; and Legg, S. M.\n\n\n \n\n\n\n Ocean Modell., 33(3-4): 224–234. 2010.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\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
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@Article{\t  klymaklegg10,\n  Title\t\t= {A Simple Mixing Scheme for Models That Resolve Breaking\n\t\t  Internal Waves},\n  Author\t= {Klymak, Jody M. and Legg, Sonya M.},\n  Year\t\t= {2010},\n  Journal\t= {Ocean Modell.},\n  Volume\t= {33},\n  Number\t= {3-4},\n  Pages\t\t= {224--234},\n  DOI\t\t= {10.1016/j.ocemod.2010.02.005},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:50 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed,Parameterizations}\n}\n\n
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\n  \n 2009\n \n \n (1)\n \n \n
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\n \n\n \n \n \n \n \n Estimates of Mixing.\n \n \n \n\n\n \n Klymak, J. M.; and Nash, J. D.\n\n\n \n\n\n\n In Steele, J. H.; Turekian, K. K.; and Thorpe, S. A., editor(s), Encyclopedia of Ocean Sciences, Estimates of Mixing, pages 3696–3706. Academic Press, 2009.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@InCollection{\t  klymaknash09,\n  Title\t\t= {Estimates of Mixing},\n  BookTitle\t= {Encyclopedia of Ocean Sciences},\n  Author\t= {Klymak, Jody M. and Nash, Jonathan D.},\n  Editor\t= {Steele, John H. and Turekian, Karl K. and Thorpe, Steve\n\t\t  A.},\n  Year\t\t= {2009},\n  Pages\t\t= {3696--3706},\n  Publisher\t= {Academic Press},\n  DOI\t\t= {DOI: 10.1016/B978-012374473-9.00615-9},\n  Chapter\t= {Estimates of Mixing},\n  date-modified\t= {2021-06-10 16:43:30 -0700},\n  jmkpubtype\t= {inbook},\n  Keywords\t= {jmkinbook}\n}\n\n
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\n  \n 2008\n \n \n (4)\n \n \n
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\n \n\n \n \n \n \n \n Assessing the State of the Art of Ocean Internal Wave Research.\n \n \n \n\n\n \n Alford, M.; and Klymak, J.\n\n\n \n\n\n\n Eos Trans. AGU, 89: 52. 2008.\n \n\n\n\n
\n\n\n\n \n\n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  alfordklymak08,\n  Title\t\t= {Assessing the State of the Art of Ocean Internal Wave\n\t\t  Research},\n  Author\t= {Alford, M. and Klymak, J.},\n  Year\t\t= {2008},\n  Journal\t= {Eos Trans. AGU},\n  Volume\t= {89},\n  Pages\t\t= {52},\n  copyright\t= {All rights reserved},\n  date-added\t= {2010-03-05 15:07:48 -0800},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {other},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Direct Breaking of the Internal Tide near Topography: Kaena Ridge, Hawaii.\n \n \n \n\n\n \n Klymak, J. M.; Pinkel, R.; and Rainville, L.\n\n\n \n\n\n\n J. Phys. Oceanogr., 38: 380–399. 2008.\n \n\n\n\n
\n\n\n\n \n\n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  klymaketal08,\n  Title\t\t= {Direct Breaking of the Internal Tide near Topography:\n\t\t  {{Kaena Ridge}}, {{Hawaii}}},\n  Author\t= {Klymak, Jody M. and Pinkel, Robert and Rainville, Luc},\n  Year\t\t= {2008},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {38},\n  Pages\t\t= {380--399},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Internal Hydraulic Jumps and Overturning Generated by Tidal Flow over a Tall Steep Ridge.\n \n \n \n\n\n \n Legg, S.; and Klymak, J. M.\n\n\n \n\n\n\n J. Phys. Oceanogr., 38(9): 1949–1964. 2008.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  leggklymak08,\n  Title\t\t= {Internal Hydraulic Jumps and Overturning Generated by\n\t\t  Tidal Flow over a Tall Steep Ridge},\n  Author\t= {Legg, Sonya and Klymak, Jody M.},\n  Year\t\t= {2008},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {38},\n  Number\t= {9},\n  Pages\t\t= {1949--1964},\n  DOI\t\t= {10.1175/2008JPO3777.1},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  vol\t\t= {38},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Small Scale Processes in the Coastal Ocean.\n \n \n \n\n\n \n Moum, J. N.; Nash, J. D.; and Klymak, J. M.\n\n\n \n\n\n\n Oceanography, 21(4). 2008.\n \n\n\n\n
\n\n\n\n \n\n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  moumetal08,\n  Title\t\t= {Small Scale Processes in the Coastal Ocean},\n  Author\t= {Moum, James N. and Nash, Jonathan D. and Klymak, Jody M.},\n  Year\t\t= {2008},\n  Journal\t= {Oceanography},\n  Volume\t= {21},\n  Number\t= {4},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n  \n 2007\n \n \n (5)\n \n \n
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\n \n\n \n \n \n \n \n Internal Waves across the Pacific.\n \n \n \n\n\n \n Alford, M. H.; MacKinnon, J. A.; Zhao, Z.; Pinkel, R.; Klymak, J.; and Peacock, T.\n\n\n \n\n\n\n Geophys. Res. Lett., 34(L24601). 2007.\n \n\n\n\n
\n\n\n\n \n\n \n \n doi\n  \n \n\n \n link\n  \n \n\n bibtex\n \n\n \n\n \n\n \n \n \n \n \n \n \n\n  \n \n \n \n \n\n\n\n
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@Article{\t  alfordetal07,\n  Title\t\t= {Internal Waves across the {{Pacific}}},\n  Author\t= {Alford, M. H. and MacKinnon, J. A. and Zhao, Z. and\n\t\t  Pinkel, R. and Klymak, J. and Peacock, T.},\n  Year\t\t= {2007},\n  Journal\t= {Geophys. Res. Lett.},\n  Volume\t= {34},\n  Number\t= {L24601},\n  DOI\t\t= {doi:10.1029/2007GL031566},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/4FBY8GYP/Alford et al. -\n\t\t  2007 - Internal waves across the Pacific.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Oceanic Isopycnal Slope Spectra. Part II: Turbulence.\n \n \n \n\n\n \n Klymak, J.; and Moum, J.\n\n\n \n\n\n\n J. Phys. Oceanogr., 37(5): 1232–1245. 2007.\n \n\n\n\n
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@Article{\t  klymakmoum07,\n  Title\t\t= {Oceanic Isopycnal Slope Spectra. {{Part II}}:\n\t\t  {{Turbulence}}},\n  Author\t= {Klymak, J.M. and Moum, J.N.},\n  Year\t\t= {2007},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {37},\n  Number\t= {5},\n  Pages\t\t= {1232--1245},\n  date-added\t= {2011-02-12 09:14:43 -0800},\n  date-modified\t= {2021-06-10 17:48:27 -0700},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Oceanic Isopycnal Slope Spectra. Part I: Internal Waves.\n \n \n \n\n\n \n Klymak, J. M.; and Moum, J. N.\n\n\n \n\n\n\n J. Phys. Oceanogr., 37(5): 1215–1231. 2007.\n \n\n\n\n
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@Article{\t  klymakmoum07a,\n  Title\t\t= {Oceanic Isopycnal Slope Spectra. {{Part I}}: {{Internal}}\n\t\t  Waves},\n  Author\t= {Klymak, Jody M. and Moum, James N.},\n  Year\t\t= {2007},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {37},\n  Number\t= {5},\n  Pages\t\t= {1215--1231},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Energy Transport by Nonlinear Internal Waves.\n \n \n \n\n\n \n Moum, J. N.; Klymak, J. M.; Nash, J. D.; Perlin, A.; and Smyth, W. D.\n\n\n \n\n\n\n J. Phys. Oceanogr., 37: 1968–1988. 2007.\n \n\n\n\n
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@Article{\t  moumetal07,\n  Title\t\t= {Energy Transport by Nonlinear Internal Waves},\n  Author\t= {Moum, James N. and Klymak, Jody M. and Nash, Jonathan D.\n\t\t  and Perlin, Alexander and Smyth, William D.},\n  Year\t\t= {2007},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {37},\n  Pages\t\t= {1968--1988},\n  DOI\t\t= {10.1175/JPO3094.1},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Organization of Stratification, Turbulence, and Veering in Bottom Ekman Layers.\n \n \n \n\n\n \n Perlin, A.; Moum, J.; Klymak, J.; Levine, M.; Boyd, T.; and Kosro, M.\n\n\n \n\n\n\n J. Geophys. Res., 112. 2007.\n \n\n\n\n
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@Article{\t  perlinetal07,\n  Title\t\t= {Organization of Stratification, Turbulence, and Veering in\n\t\t  Bottom {{Ekman}} Layers},\n  Author\t= {Perlin, A. and Moum, J.N. and Klymak, J.M. and Levine,\n\t\t  M.D. and Boyd, T. and Kosro, M.},\n  Year\t\t= {2007},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {112},\n  DOI\t\t= {10.1029/2004JC002641},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/AT7AIPLQ/Perlin et al. -\n\t\t  2007 - Organization of stratification, turbulence, and\n\t\t  veering in bottom Ekman layers.pdf}\n}\n\n
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\n  \n 2006\n \n \n (3)\n \n \n
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\n \n\n \n \n \n \n \n Prototypical Solitons in the South China Sea.\n \n \n \n\n\n \n Klymak, J. M.; Pinkel, R.; Liu, C.; Liu, A. K.; and David, L.\n\n\n \n\n\n\n Geophys. Res. Lett., 33: doi:10.1029/2006GL025932. 2006.\n \n\n\n\n
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@Article{\t  klymaketal06a,\n  Title\t\t= {Prototypical Solitons in the {{South China Sea}}},\n  Author\t= {Klymak, Jody M. and Pinkel, Robert and Liu, Cho-Teng and\n\t\t  Liu, Anthony K. and David, Laura},\n  Year\t\t= {2006},\n  Journal\t= {Geophys. Res. Lett.},\n  Volume\t= {33},\n  Pages\t\t= {doi:10.1029/2006GL025932},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n An Estimate of Tidal Energy Lost to Turbulence at the Hawaiian Ridge.\n \n \n \n\n\n \n Klymak, J. M.; Moum, J. N.; Nash, J. D.; Kunze, E.; Girton, J. B.; Carter, G. S.; Lee, C. M.; Sanford, T. B.; and Gregg, M. C.\n\n\n \n\n\n\n J. Phys. Oceanogr., 36: 1148–1164. 2006.\n \n\n\n\n
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@Article{\t  klymaketal06b,\n  Title\t\t= {An Estimate of Tidal Energy Lost to Turbulence at the\n\t\t  {{Hawaiian Ridge}}},\n  Author\t= {Klymak, Jody M. and Moum, James N. and Nash, Jonathan D.\n\t\t  and Kunze, Eric and Girton, James B. and Carter, Glenn S.\n\t\t  and Lee, Craig M. and Sanford, Thomas B. and Gregg, Micahel\n\t\t  C.},\n  Year\t\t= {2006},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {36},\n  Pages\t\t= {1148--1164},\n  DOI\t\t= {10.1175/JPO2885.1},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Non-Linear Internal Waves from Luzon Strait.\n \n \n \n\n\n \n Liu, C.; Pinkel, R.; Hsu, M.; Klymak, J.; Chen, H.; and Villanovy, C.\n\n\n \n\n\n\n Eos Trans.AGU, 87(42): 449–451. 2006.\n \n\n\n\n
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@Article{\t  liuetal06,\n  Title\t\t= {Non-Linear Internal Waves from {{Luzon Strait}}},\n  Author\t= {Liu, C.-T. and Pinkel, R. and Hsu, M.-K. and Klymak, J.M.\n\t\t  and Chen, H.-W. and Villanovy, C.},\n  Year\t\t= {2006},\n  Journal\t= {Eos Trans.AGU},\n  Volume\t= {87},\n  Number\t= {42},\n  Pages\t\t= {449--451},\n  DOI\t\t= {10.1029/2006EO420002},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n A Modified Law-of-the-Wall Applied to Oceanic Bottom Boundary Layers.\n \n \n \n\n\n \n Perlin, A.; Moum, J.; Klymak, J.; Levine, M.; Boyd, T.; and Kosro, M.\n\n\n \n\n\n\n J. Geophys. Res., 110(C10S10): doi:10.1029/2004JC002310. 2005.\n \n\n\n\n
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@Article{\t  perlinetal05a,\n  Title\t\t= {A Modified Law-of-the-Wall Applied to Oceanic Bottom\n\t\t  Boundary Layers},\n  Author\t= {Perlin, A. and Moum, J.N. and Klymak, J.M. and Levine,\n\t\t  M.D. and Boyd, T. and Kosro, M.},\n  Year\t\t= {2005},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {110},\n  Number\t= {C10S10},\n  Pages\t\t= {doi:10.1029/2004JC002310},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  read\t\t= {1},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Response of the Bottom Boundary Layer over a Sloping Shelf to Variations in Along-Shore Wind.\n \n \n \n\n\n \n Perlin, A.; Moum, J.; and Klymak, J.\n\n\n \n\n\n\n J. Geophys. Res., 110(C10S09). 2005.\n \n\n\n\n
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@Article{\t  perlinetal05b,\n  Title\t\t= {Response of the Bottom Boundary Layer over a Sloping Shelf\n\t\t  to Variations in Along-Shore Wind},\n  Author\t= {Perlin, A. and Moum, J.N. and Klymak, J.M.},\n  Year\t\t= {2005},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {110},\n  Number\t= {C10S09},\n  DOI\t\t= {10.1029/2004JC002500},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:43:13 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/P5TJXM6T/Perlin et al. -\n\t\t  2005 - Response of the bottom boundary layer over a sloping\n\t\t  shelf to variations in along-shore wind.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Tidally Generated Turbulence over the Knight Inlet Sill.\n \n \n \n\n\n \n Klymak, J. M.; and Gregg, M. C.\n\n\n \n\n\n\n J. Phys. Oceanogr., 34(5): 1135–1151. 2004.\n \n\n\n\n
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@Article{\t  klymakgregg04,\n  Title\t\t= {Tidally Generated Turbulence over the {{Knight Inlet}}\n\t\t  Sill},\n  Author\t= {Klymak, Jody M. and Gregg, Michael C.},\n  Year\t\t= {2004},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {34},\n  Number\t= {5},\n  Pages\t\t= {1135--1151},\n  DOI\t\t= {10.1175/1520-0485(2004)034<1135:TGTOTK>2.0.CO;2},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:37:10 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/5YHWDAG2/Klymak and Gregg -\n\t\t  2004 - Tidally generated turbulence over the Knight Inlet\n\t\t  sill.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Convectively-Driven Mixing in the Bottom Boundary Layer.\n \n \n \n\n\n \n Moum, J. N.; Perlin, A.; Klymak, J.; Levine, M.; Boyd, T.; and Kosro, M.\n\n\n \n\n\n\n J. Phys. Oceanogr., 34: 2189–2202. 2004.\n \n\n\n\n
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@Article{\t  moumetal04,\n  Title\t\t= {Convectively-Driven Mixing in the Bottom Boundary Layer},\n  Author\t= {Moum, J. N. and Perlin, A. and Klymak, J.M. and Levine,\n\t\t  M.D. and Boyd, T. and Kosro, M.},\n  Year\t\t= {2004},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {34},\n  Pages\t\t= {2189--2202},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:37:10 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Form Drag and Mixing Due to Tidal Flow Past a Sharp Point.\n \n \n \n\n\n \n Edwards, K. A.; MacCready, P.; Moum, J. N.; Pawlak, G.; Klymak, J. M.; and Perlin, A.\n\n\n \n\n\n\n J. Phys. Oceanogr., 34: 1297–1312. 2003.\n \n\n\n\n
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@Article{\t  edwardsetal03,\n  Title\t\t= {Form Drag and Mixing Due to Tidal Flow Past a Sharp\n\t\t  Point},\n  Author\t= {Edwards, Kathleen A. and MacCready, Parker and Moum, James\n\t\t  N. and Pawlak, Geno and Klymak, Jody M. and Perlin,\n\t\t  Alexander},\n  Year\t\t= {2003},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {34},\n  Pages\t\t= {1297--1312},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:36:53 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n The Role of Upstream Waves and a Downstream Density-Pool in the Growth of Lee-Waves: Stratified Flow over the Knight Inlet Sill.\n \n \n \n\n\n \n Klymak, J. M.; and Gregg, M. C.\n\n\n \n\n\n\n J. Phys. Oceanogr., 33(7): 1446–1461. 2003.\n \n\n\n\n
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@Article{\t  klymakgregg03,\n  Title\t\t= {The Role of Upstream Waves and a Downstream Density-Pool\n\t\t  in the Growth of Lee-Waves: Stratified Flow over the\n\t\t  {{Knight Inlet}} Sill},\n  Author\t= {Klymak, Jody M. and Gregg, Michael C.},\n  Year\t\t= {2003},\n  Journal\t= {J. Phys. Oceanogr.},\n  Volume\t= {33},\n  Number\t= {7},\n  Pages\t\t= {1446--1461},\n  DOI\t\t= {10.1175/1520-0485(2003)033<1446:TROUWA>2.0.CO;2},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:37:00 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/YSINL7FL/Klymak and Gregg -\n\t\t  2003 - The role of upstream waves and a downstream\n\t\t  density-pool in the growth of lee-waves stratified\n\t\t  flow.pdf}\n}\n\n
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\n \n\n \n \n \n \n \n Internal Solitary Waves of Elevation Advancing on a Shoaling Shelf.\n \n \n \n\n\n \n Klymak, J. M.; and Moum, J. N.\n\n\n \n\n\n\n Geophys. Res. Lett., 30(2045): 10.1029/2003GL017706. 2003.\n \n\n\n\n
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@Article{\t  klymakmoum03,\n  Title\t\t= {Internal Solitary Waves of Elevation Advancing on a\n\t\t  Shoaling Shelf},\n  Author\t= {Klymak, Jody M. and Moum, James N.},\n  Year\t\t= {2003},\n  Journal\t= {Geophys. Res. Lett.},\n  Volume\t= {30},\n  Number\t= {2045},\n  Pages\t\t= {10.1029/2003GL017706},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:36:44 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n From Tides to Mixing along the Hawaiian Ridge.\n \n \n \n\n\n \n Rudnick, D. L.; Boyd, T. J.; Brainard, R. E.; Carter, G. S.; Egbert, G. D.; Gregg, M. C.; Holloway, P. E.; Klymak, J. M.; Kunze, E.; Lee, C. M.; Levine, M. D.; Luther, D. S.; Martin, J. P.; Merrifield, M. A.; Moum, J. N.; Nash, J. D.; Pinkel, R.; Rainville, L.; and Sanford, T. B.\n\n\n \n\n\n\n Science, 301(5631): 355–357. 2003.\n \n\n\n\n
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@Article{\t  rudnicketal03,\n  Title\t\t= {From Tides to Mixing along the {{Hawaiian Ridge}}},\n  Author\t= {Rudnick, Daniel L. and Boyd, Timothy J. and Brainard,\n\t\t  Russell E. and Carter, Glenn S. and Egbert, Gary D. and\n\t\t  Gregg, Michael C. and Holloway, Peter E. and Klymak, Jody\n\t\t  M. and Kunze, Eric and Lee, Craig M. and Levine, Murray D.\n\t\t  and Luther, Douglas S. and Martin, Joseph P. and\n\t\t  Merrifield, Mark A. and Moum, James N. and Nash, Jonathan\n\t\t  D. and Pinkel, Robert and Rainville, Luc and Sanford,\n\t\t  Thomas B.},\n  Year\t\t= {2003},\n  Journal\t= {Science},\n  Volume\t= {301},\n  Number\t= {5631},\n  Pages\t\t= {355--357},\n  DOI\t\t= {10.1126/science.1085837},\n  Abstract\t= {The cascade from tides to turbulence has been hypothesized\n\t\t  to serve as a major energy pathway for ocean mixing. We\n\t\t  investigated this cascade along the Hawaiian Ridge using\n\t\t  observations and numerical models. A divergence of internal\n\t\t  tidal energy flux observed at the ridge agrees with the\n\t\t  predictions of internal tide models. Large internal tidal\n\t\t  waves with peak-to-peak amplitudes of up to 300 meters\n\t\t  occur on the ridge. Internal-wave energy is enhanced, and\n\t\t  turbulent dissipation in the region near the ridge is 10\n\t\t  times larger than open-ocean values. Given these major\n\t\t  elements in the tides-to-turbulence cascade, an energy\n\t\t  budget approaches closure.},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2023-08-25 15:02:04 -0700},\n  jmkpubtype\t= {refereed,ClassProj},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/78CGIWRR/Rudnick et al. -\n\t\t  2003 - From tides to mixing along the Hawaiian Ridge.pdf}\n}\n\n
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\n The cascade from tides to turbulence has been hypothesized to serve as a major energy pathway for ocean mixing. We investigated this cascade along the Hawaiian Ridge using observations and numerical models. A divergence of internal tidal energy flux observed at the ridge agrees with the predictions of internal tide models. Large internal tidal waves with peak-to-peak amplitudes of up to 300 meters occur on the ridge. Internal-wave energy is enhanced, and turbulent dissipation in the region near the ridge is 10 times larger than open-ocean values. Given these major elements in the tides-to-turbulence cascade, an energy budget approaches closure.\n
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\n  \n 2001\n \n \n (2)\n \n \n
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\n \n\n \n \n \n \n \n The Three-Dimensional Nature of Flow near a Sill.\n \n \n \n\n\n \n Klymak, J. M.; and Gregg, M. C.\n\n\n \n\n\n\n J. Geophys. Res., 106(C10): 22,295–22,311. 2001.\n \n\n\n\n
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@Article{\t  klymakgregg01,\n  Title\t\t= {The Three-Dimensional Nature of Flow near a Sill},\n  Author\t= {Klymak, Jody M. and Gregg, Michael C.},\n  Year\t\t= {2001},\n  Journal\t= {J. Geophys. Res.},\n  Volume\t= {106},\n  Number\t= {C10},\n  Pages\t\t= {22,295--22,311},\n  DOI\t\t= {10.1029/2001JC000933},\n  copyright\t= {All rights reserved},\n  date-modified\t= {2021-06-10 16:36:33 -0700},\n  jmkpubtype\t= {refereed},\n  Keywords\t= {internal waves,jmkrefereed}\n}\n\n
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\n \n\n \n \n \n \n \n Three-Dimensional Nature of Flow near a Sill.\n \n \n \n\n\n \n Klymak, J. M.; and Gregg, M. C.\n\n\n \n\n\n\n J. Geophys. Res. Oceans, 106(C10): 22295–22311. 2001.\n \n\n\n\n
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@Article{\t  klymakgregg01a,\n  Title\t\t= {Three-Dimensional Nature of Flow near a Sill},\n  Author\t= {Klymak, Jody M. and Gregg, Michael C.},\n  Year\t\t= {2001},\n  Journal\t= {J. Geophys. Res. Oceans},\n  Volume\t= {106},\n  Number\t= {C10},\n  Pages\t\t= {22295--22311},\n  DOI\t\t= {10.1029/2001JC000933},\n  URLDate\t= {2024-11-21},\n  Abstract\t= {Velocity and density sections across Knight Inlet, British\n\t\t  Columbia, demonstrate that lateral recirculations are a\n\t\t  first-order feature of the flow in the lee of the sill. The\n\t\t  flow over this sill has been used as a typical example of\n\t\t  two-dimensional hydraulics, with a lower layer that thins\n\t\t  and accelerates as it moves downstream below an almost\n\t\t  stagnant layer that widens downstream, creating a\n\t\t  distinctive wedge shape. However, we find that rather than\n\t\t  being stagnant, the velocity in this wedge-shaped layer is\n\t\t  actually quite large, consisting of a swiftly recirculating\n\t\t  dipole vortex during flood tide and a monopole vortex\n\t\t  during ebb tide, though we may have missed the matching\n\t\t  half of a dipole with our sampling during ebb. The\n\t\t  recirculations during flood tide carry an amount of water\n\t\t  equal to 25\\% of the tidal flux, while the monopole during\n\t\t  ebb tide carries 20\\% of the tidal flux. These\n\t\t  recirculations bias along-channel estimates of volume flux,\n\t\t  especially in the middle wedge-shaped layer, and\n\t\t  demonstrate that accurate volume fluxes in the lee wave are\n\t\t  only possible if three-dimensional surveys are made. Our\n\t\t  three-dimensional survey shows that there is a net\n\t\t  isopycnal convergence of water in the middle layer at a\n\t\t  rate adequate to close the volume budget of the flow\n\t\t  without recourse to diapycnal fluxes. We also calculate the\n\t\t  strength of the vorticity in the recirculations observed\n\t\t  during flood tide and attribute their formation to boundary\n\t\t  layer separation.},\n  copyright\t= {All rights reserved},\n  langid\t= {english},\n  Keywords\t= {jmkrefereed},\n  File\t\t= {/Users/jklymak/Zotero/storage/HD8NKM8D/Klymak and Gregg -\n\t\t  2001 - Three-dimensional nature of flow near a\n\t\t  sill.pdf;/Users/jklymak/Zotero/storage/AYRQN8RA/2001JC000933.html}\n}\n\n
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\n Velocity and density sections across Knight Inlet, British Columbia, demonstrate that lateral recirculations are a first-order feature of the flow in the lee of the sill. The flow over this sill has been used as a typical example of two-dimensional hydraulics, with a lower layer that thins and accelerates as it moves downstream below an almost stagnant layer that widens downstream, creating a distinctive wedge shape. However, we find that rather than being stagnant, the velocity in this wedge-shaped layer is actually quite large, consisting of a swiftly recirculating dipole vortex during flood tide and a monopole vortex during ebb tide, though we may have missed the matching half of a dipole with our sampling during ebb. The recirculations during flood tide carry an amount of water equal to 25% of the tidal flux, while the monopole during ebb tide carries 20% of the tidal flux. These recirculations bias along-channel estimates of volume flux, especially in the middle wedge-shaped layer, and demonstrate that accurate volume fluxes in the lee wave are only possible if three-dimensional surveys are made. Our three-dimensional survey shows that there is a net isopycnal convergence of water in the middle layer at a rate adequate to close the volume budget of the flow without recourse to diapycnal fluxes. We also calculate the strength of the vorticity in the recirculations observed during flood tide and attribute their formation to boundary layer separation.\n
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\n \n\n \n \n \n \n \n Stratified Flow Separation in the Lee of the Knight Inlet Sill.\n \n \n \n\n\n \n Klymak, J. M.; and Gregg, M. C.\n\n\n \n\n\n\n In Proc. IAHR 5th Int. Symp. Stratif. Flows, 2000. \n \n\n\n\n
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@InProceedings{\t  klymakgregg00,\n  Title\t\t= {Stratified Flow Separation in the Lee of the {{Knight\n\t\t  Inlet}} Sill},\n  BookTitle\t= {Proc. {{IAHR}} 5th {{Int}}. {{Symp}}. {{Stratif}}.\n\t\t  {{Flows}}},\n  Author\t= {Klymak, Jody M. and Gregg, Michael C.},\n  Year\t\t= {2000},\n  date-modified\t= {2021-06-10 16:36:33 -0700},\n  jmkpubtype\t= {other},\n  Keywords\t= {jmkother}\n}\n\n
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