论文信息 - Observations of internal wave packets propagating along‐shelf in northern Monterey Bay - 字舞流文

Observations of internal wave packets propagating along‐shelf in northern Monterey Bay

Internal waves of depression were observed propagating along-shelf and into northern Monterey Bay, California (CA) on the inner shelf. These waves had amplitudes approximately equal to the thermocline depth (∼4 m), and were unstable to shear and mix the thermocline. Isopycnal gradient spectra showed that the wave packets lead to an elevated mean dissipation rate of ɛ = 2.63 × 10−5 m3 s−2 for up to 2 hours after wave passage. The proximity to the surface created strong surface convergences that can actively transport buoyant material, such as plankton, back into the bay. The wave packets were observed regularly over the upwelling season across multiple years suggesting they may have large effects on the documented spatial variation of phytoplankton and larvae on the inner shelf. The timing of the waves suggests they are not formed by tides interacting with bathymetry, but are generated by buoyant plume propagation.

John P. Ryan | Libe Washburn | John A. Barth | Tarik C. Gouhier | Malin L. Pinsky | Alison J. Haupt | Margaret A. McManus | Alison C. Iles | J. Ryan | C. B. Woodson | S. Teck | J. Barth | L. Washburn | M. McManus | O. Cheriton | A. Iles | T. Gouhier | A. Haupt | Sarah J. Teck | Olivia M. Cheriton | K. N. Carden | Brian S. Cheng | Joana Fernandes | L. E. Garske | K. T. Honey | M. F. Hubbard | L. Kara | M. C. Lynch | B. Mahoney | M. Pfaff | M. J. Robart | Julia S. Stewart | A. True | J. S. Stewart | M. Robart | M. Pinsky | B. Mahoney | M. Hubbard | C. Woodson | J. Fernandes | M. Pfaff | K. Honey | K. N. Carden | B. S. Cheng | L. Kara | A. True

[1] J. Klymak,et al. Oceanic Isopycnal Slope Spectra. Part I: Internal Waves , 2007 .

[2] Efim Pelinovsky,et al. Solitary wave transformation in a medium with sign-variable quadratic nonlinearity and cubic nonlinearity , 1999 .

[3] B. Holt,et al. SEASAT views oceans and sea ice with synthetic aperture radar , 1982 .

[4] C. Garrett,et al. A Simple Model for the Shear-induced Decay of an Internal Solitary Wave , 1993 .

[5] J. Hare,et al. Larval transport and dispersal in the coastal ocean and consequences for population connectivity , 2007 .

[6] Rob A. Hall,et al. Internal Tides in Monterey Submarine Canyon , 2002 .

[7] O. Lee. OBSERVATIONS ON INTERNAL WAVES IN SHALLOW WATER , 1961 .

[8] J. Pineda,et al. Observation of very large and steep internal waves of elevation near the Massachusetts coast , 2004 .

[9] R. Lien,et al. Internal waves, solitary-like waves, and mixing on the Monterey Bay shelf , 2005 .

[10] Shoaling solitary internal waves: on a criterion for the formation of waves with trapped cores , 2003, Journal of Fluid Mechanics.

[11] Richard P. Trask,et al. Detection of Massachusetts Bay internal waves by the synthetic aperture radar (SAR) on SEASAT , 1983 .

[12] E. D’Asaro,et al. High-Frequency Internal Waves on the Oregon Continental Shelf , 2007 .

[13] D. Jeans,et al. The variability of strongly non-linear solitary internal waves observed during an upwelling season on the Portuguese shelf , 2001 .

[14] A. M. Davies,et al. Nonlinear interaction between wind‐forced currents and near‐inertial oscillations and internal waves in nearshore frontal regions , 2005 .

[15] J. Largier,et al. Upwelling shadows as nearshore retention sites: the example of northern Monterey Bay , 1997 .

[16] John P. Ryan,et al. Northern Monterey Bay upwelling shadow front : observations of a coastally and surface-trapped buoyant plume , 2009 .

[17] Roger Grimshaw,et al. RESONANT FLOW OF A STRATIFIED FLUID OVER TOPOGRAPHY , 1986 .

[18] M. Barad,et al. Simulations of shear instabilities in interfacial gravity waves , 2010, Journal of Fluid Mechanics.

[19] G. S. Thapar. Department of Zoology. , 1953 .

[20] J. Nash,et al. Energy Transport by Nonlinear Internal Waves , 2007 .

[21] Andrew M. Fischer,et al. Coastal Ocean Physics and Red Tides: An Example from Monterey Bay, California , 2005 .

[22] Johanna H. Rosman,et al. Extracting Reynolds Stresses from Acoustic Doppler Current Profiler Measurements in Wave-Dominated Environments , 2008 .

[23] A. M. Davies,et al. The Effect of a Bottom Shelf Front upon the Generation and Propagation of Near-Inertial Internal Waves in the Coastal Ocean , 2005 .

[24] Andrew M. Fischer,et al. A coastal ocean extreme bloom incubator , 2008 .

[25] V. Vlasenko,et al. Generation of internal waves by a supercritical stratified plume , 2009 .

[26] J. Nash,et al. River plumes as a source of large-amplitude internal waves in the coastal ocean , 2005, Nature.

[27] Franklin B. Schwing,et al. Bifurcated flow from an upwelling center: a cold water source for Monterey Bay , 1994 .

[28] J. Klymak,et al. Oceanic Isopycnal Slope Spectra. Part II: Turbulence , 2007 .

[29] D. Jeans,et al. The evolution and energetics of large amplitude nonlinear internal waves on the Portuguese shelf , 2001 .

[30] J. Klymak,et al. Internal solitary waves of elevation advancing on a shoaling shelf , 2003 .

[31] R. Ferrari,et al. Frontogenesis, and the Stratification of the Surface Mixed Layer, , 2008 .