Mean and Near-Inertial Ocean Current Response to Hurricane Gilbert

Shay, Lynn K.; Mariano, Arthur J.; Jacob, Samuel; Ryan, Edward H.

doi:10.1175/1520-0485(1998)028<0858:manioc>2.0.co;2

Cited by 87 publications

(97 citation statements)

References 35 publications

(82 reference statements)

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“…Second, upwelling occurs behind a typhoon because of the cyclonic circulation of the surface winds (Price 1981;Wada 2002). When the translation speed of a typhoon is lower than the phase speed of the first baroclinic mode, this upwelling plays an essential role in causing sea surface cooling because a cold wake is formed behind the typhoon (Shay et al 1998).…”

Section: Resultsmentioning

confidence: 99%

Typhoon-induced sea surface cooling during the 2011 and 2012 typhoon seasons: observational evidence and numerical investigations of the sea surface cooling effect using typhoon simulations

Wada

Uehara

Ishizaki

2014

Prog Earth Planet Sci

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Understanding oceanic responses to typhoons and the impacts those responses have on the typhoons themselves is important so that typhoon predictions performed using numerical models and typhoon forecasts can be improved. However, in situ oceanic observations underneath typhoons are still limited. To gain a deep understanding of the oceanic response and estimate the magnitude of its impact, three profiling floats were deployed in the western North Pacific during the 2011 and 2012 typhoon seasons. The daily observations showed that the sea surface cooled by more than 2°C in typhoons Ma-on and Muifa in 2011, and typhoons Bolaven and Parapiroon in 2012. The response was different at different float locations relative to the typhoon center, that is, the response within 100 km of the typhoon center was different to the response more than 100 km from the center on the right-or left-hand sides of the typhoon track, even though the response was affected by pre-existing oceanic conditions, precipitation, and the typhoon intensity. The salinity and temperature profiles were also considerably different before, during, and after the passage of a typhoon. To determine the impacts of typhoon-induced sea surface cooling on typhoon predictions, the impacts of the four typhoons were numerically evaluated using an atmosphere-wave-ocean coupled model. The coupled model simulated sea surface cooling and the resultant increases in the central pressures caused by the passages of the typhoons reasonably well. When axisymmetrically simulated, the mean sea surface cooling beneath a typhoon decreased the latent heat fluxes by 24% to 47%. A larger cooling effect gave a larger decrease in the latent heat flux only during the intensification phase. The decrease in the latent heat flux affected the inner core structure, particularly in the inflow boundary layer and around the eyewall. The cooling effect significantly affected the track simulation only for Typhoon Muifa, which had the weakest zonal steering flow of the four typhoons. These results suggest that making more frequent typhoon observations using profiling floats, further developing oceanic analysis techniques, and improving our understanding of typhoon-ocean interactions are required to produce more accurate typhoon predictions.

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Section: Resultsmentioning

confidence: 99%

Typhoon-induced sea surface cooling during the 2011 and 2012 typhoon seasons: observational evidence and numerical investigations of the sea surface cooling effect using typhoon simulations

Wada

Uehara

Ishizaki

2014

Prog Earth Planet Sci

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“…However, background variability can contaminate the TC signal for larger horizontal constraints (e.g., 0.5 • ). Furthermore, horizontal velocities within western boundary ocean currents (e.g., the Gulf Stream) and geostrophic vortices within TC regions are typically on the order of O (10-100) cm s −1 (Shay et al, 1998 3. All of the Argo pairs are within 8 • relative to the center of the storm track, perpendicular to the storm's direction of translation.…”

Section: Composite Footprint Methodsmentioning

confidence: 99%

Global representation of tropical cyclone-induced short-term ocean thermal changes using Argo data

2015

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Abstract. Argo floats are used to examine tropical cyclone (TC) induced ocean thermal changes on the global scale by comparing temperature profiles before and after TC passage. We present a footprint method that analyzes cross-track thermal responses along all storm tracks during the period 2004-2012. We combine the results into composite representations of the vertical structure of the average thermal response for two different categories: tropical storms/tropical depressions (TS/TD) and hurricanes. The two footprint composites are functions of three variables: cross-track distance, water depth and time relative to TC passage. We find that this footprint strategy captures the major features of the upperocean thermal response to TCs on timescales up to 20 days when compared against previous case study results using in situ measurements. On the global scale, TCs are responsible for 1.87 PW (11.05 W m −2 ) of heat transfer annually from the global ocean to the atmosphere during storm passage (0-3 days). Of this total, 1.05 ± 0.20 PW (4.80 ± 0.85 W m −2 ) is caused by TS/TD and 0.82 ± 0.21 PW (6.25 ± 1.5 W m −2 ) is caused by hurricanes. Our findings indicate that ocean heat loss by TCs may be a substantial missing piece of the global ocean heat budget. Changes in ocean heat content (OHC) after storm passage are estimated by analyzing the temperature anomalies during wake recovery following storm events (4-20 days after storm passage) relative to pre-storm conditions. Results indicate the global ocean experiences a 0.75 ± 0.25 PW (5.98 ± 2.1 W m −2 ) heat gain annually for hurricanes. In contrast, under TS/TD conditions, the ocean experiences 0.41 ± 0.21 PW (1.90 ± 0.96 W m −2 ) ocean heat loss, suggesting the overall oceanic thermal response is particularly sensitive to the intensity of the event. The ocean heat uptake caused by all storms during the restorative stage is 0.34 PW.

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“…The LC returns to its southern location, where water from the Yucatan Current flows more directly toward the Straits of Florida, after the northern extension of the LC is pinched off. This process forms large anticyclonic rings which then propagate westward at speeds of 2 to 5 km d −1 , with a lifetime of days to ~1 yr (Elliott 1982, Forristall et al 1992, Shay et al 1998. These anticyclonic rings have radii of ~150 km and swirl speeds of 1.8 to 2 m s −1 and can reach ~800 m depth (Oey et al 2005).…”

Section: Introductionmentioning

confidence: 99%

Varying mesoscale structures influence larval fish distribution in the northern Gulf of Mexico

David

Bringas²,

Goñi³

et al. 2012

Mar. Ecol. Prog. Ser.

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The variability of mesoscale circulation structures in the Gulf of Mexico (GOM) was examined using satellite altimeter data collected between 1992 and 2008, and linkages between ocean circulation and the spatial distribution of larval fish were assessed. The abundance and distribution of the larvae of 5 pelagic fish taxa (Auxis spp., Euthynnus alleteratus, Thunnus thynnus, other Thunnus spp., and Coryphaena spp.) were estimated from surveys conducted by the National Oceanic and Atmospheric Administration National Marine Fisheries Service each spring between 1993 and 2007. We observed a tendency for higher northward extension of the Loop Current (LC) during spring each year, with maximum northern penetration in summer, although the exact location of the LC varied from year to year. Generally, higher total larval abundances occurred during years of high northward penetration in a region that was crossed by the LC during its excursions. However, the interannual variability of the LC was not mirrored in a general increase or decrease of larval fish densities in the water masses out of the LC front. Further, the results show that larvae of T. thynnus and Auxis spp. were more abundant within the boundaries of anticyclonic features (usually between 148 to 158 cm of sea surface height) and within GOM common waters, defined as the background waters in between the boundaries of mesoscale features. Our findings suggest that the position and strength of anticyclone mesoscale features in the GOM define a favorable spawning habitat for the species examined. KEY WORDS: Fisheries oceanography · Mesoscale variability · Fronts and eddies · Loop Current · Ichthyoplankton distribution · Thunnus thynnusResale or republication not permitted without written consent of the publisher

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Mean and Near-Inertial Ocean Current Response to Hurricane Gilbert

Cited by 87 publications

References 35 publications

Typhoon-induced sea surface cooling during the 2011 and 2012 typhoon seasons: observational evidence and numerical investigations of the sea surface cooling effect using typhoon simulations

Typhoon-induced sea surface cooling during the 2011 and 2012 typhoon seasons: observational evidence and numerical investigations of the sea surface cooling effect using typhoon simulations

Global representation of tropical cyclone-induced short-term ocean thermal changes using Argo data

Varying mesoscale structures influence larval fish distribution in the northern Gulf of Mexico

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