Refraction and reflection of infragravity waves near submarine canyons

Thomson, Jim; Elgar, Steve; Herbers, T. H. C.; Raubenheimer, Britt; Guza, R. T.

doi:10.1029/2007jc004227

Cited by 28 publications

(25 citation statements)

References 51 publications

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“…Although most of the free IG wave energy is refractively trapped or dissipated at coastlines, some of the energy leaks into the deep ocean [ Munk et al ., ; van Dongeren and Svendsen , ; Thomson et al ., ; Dolenc et al ., ; Uchiyama and McWilliams , ]. Once there, free IG waves can propagate across the ocean basin with little attenuation [e.g., Snodgrass et al ., ; Shillington , ].…”

Section: Introductionmentioning

confidence: 99%

The sources of deep ocean infragravity waves observed in the North Atlantic Ocean

Crawford

Ballu

Bertin

et al. 2015

J. Geophys. Res. Oceans

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Infragravity waves are long-period (25-250 s) ocean surface gravity waves generated in coastal zones through wave-wave interactions or oscillation of the breaking point. Most of the infragravity wave energy is trapped or dissipated near coastlines, but a small percentage escapes into the open oceans. The source of deep ocean infragravity waves is debated, specifically whether they come mostly from regions with strong source waves or from sites with particular morphologies/orientations. We correlate measurements of infragravity waves in the deep North Atlantic Ocean with infragravity wave generation parameters throughout the Atlantic Ocean to find the dominant sources of deep ocean infragravity wave energy in the North Atlantic Ocean. The deep ocean infragravity wave data are from a 5 year deployment of absolute pressure gauges west of the Azores islands (378N, 358W) and shorter data sets from seafloor tsunami gauges (DART buoys). Two main sources are identified: one off of the west coast of southern Europe and northern Africa (258N-408N) in northern hemisphere winter and the other off the west coast of equatorial Africa (the Gulf of Guinea) in southern hemisphere winter. These regions have relatively weak source waves and weak infragravity wave propagation paths to the main measurement site, indicating that that the site morphology/orientation dominates the creation of deep ocean infragravity waves. Both regions have also been identified as potential sources of global seismological noise, suggesting that the same mechanisms may be behind the generation of deep ocean infragravity waves and global seismological noise in the frequency band from 0.001 to 0.04 Hz.

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Section: Introductionmentioning

confidence: 99%

The sources of deep ocean infragravity waves observed in the North Atlantic Ocean

Crawford

Ballu

Bertin

et al. 2015

J. Geophys. Res. Oceans

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“…[9] Wave-induced pressures and velocities were measured at 28 locations between the 5.0-m isobath and the shoreline [Thomson et al, 2006[Thomson et al, , 2007. Sensors were sampled at 2 or 16 Hz for 3072 s (51.2 min) starting every hour.…”

Section: Measurementsmentioning

confidence: 99%

“…Previous studies also have shown that nearshore circulation, including the locations of rip currents, can be controlled by nonuniformities in the offshore (i.e., outside the surfzone) bathymetry [Long and Ö zkan-Haller, 2005]. Here, the effect of strong alongshore variations in the incident wavefield (caused by an offshore submarine canyon [Long and Ö zkan-Haller, 2005;Magne et al, 2007;Thomson et al, 2007]) on setup and on alongshore flows in the surfzone is examined using field observations and simplified one-and two-dimensional momentum balances. After the theories are outlined (section 2) and the observations are described (section 3), the results are presented (section 4) and conclusions are given (section 5).…”

Section: Introductionmentioning

confidence: 99%

Wave‐driven setup and alongshore flows observed onshore of a submarine canyon

et al. 2008

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[1] The effect of alongshore variations in the incident wavefield on wave-driven setup and on alongshore flows in the surfzone is investigated using observations collected onshore of a submarine canyon. Wave heights and radiation stresses at the outer edge of the surfzone (water depth %2.5 m) varied by up to a factor of 4 and 16, respectively, over a 450 m alongshore distance, resulting in setup variations as large as 0.1 m along the shoreline (water depth %0.3 m). Even with this strong alongshore variability, wave-driven setup was dominated by the cross-shore gradient of the wave radiation stress, and setup observed in the surfzone is predicted well by a one-dimensional cross-shore momentum balance. Both cross-shore radiation stress gradients and alongshore setup gradients contributed to the alongshore flows observed in the inner surfzone when alongshore gradients in offshore wave heights were large, and a simplified alongshore momentum balance suggests that the large [O(1 kg/(s 2 m)] observed setup-induced pressure gradients can drive strong [O(1 m/s)] alongshore currents.Citation: Apotsos, A., B. Raubenheimer, S. Elgar, and R. T. Guza (2008), Wave-driven setup and alongshore flows observed onshore of a submarine canyon,

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“…This arises because a forced wave approaching the breakpoint on a steep beach will be smaller than on a beach where the bound wave has developed over a long run of incident wave groups over shallow water before reaching the break point. Comparing measurements of total infragravity wave energy in 15 m depth and 5 m depth off the Californian coast, Thomson et al (2007) found a best fit dependence of between h À1/2 and h À1 , and a scatter of values mostly confined between these limits; none of the measurements came close to an h À5 dependence. However, it should be noted that the dependence of b b on the inverse of the wave height (through the breakpoint depth) appears contrary to Baldock's (2006) suggestion since it increases the relative contribution of the bound wave for waves breaking in deeper water.…”

Section: Magnitude and Cross-shore Pattern Of Infragravity Wave Energymentioning

confidence: 92%

10.3 Waves

Huntley

2013

Treatise on Geomorphology

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Refraction and reflection of infragravity waves near submarine canyons

Cited by 28 publications

References 51 publications

The sources of deep ocean infragravity waves observed in the North Atlantic Ocean

The sources of deep ocean infragravity waves observed in the North Atlantic Ocean

Wave‐driven setup and alongshore flows observed onshore of a submarine canyon

10.3 Waves

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