Mechanism of drag coefficient saturation at strong wind speeds

Takagaki, Naohisa; Komori, Satoru; Suzuki, Naoya; Iwano, Koji; Kurose, Ryoichi

doi:10.1002/2016gl070666

Cited by 55 publications

(41 citation statements)

References 21 publications

(78 reference statements)

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“…This saturation level corresponds to a 34% increase relative to the original estimates, with saturation occurring at 12% lower wind speed threshold. Laboratory measurements of drag in high winds over short fetch must be cautiously compared to field measurements, due to the limitation of wind‐wave tanks to develop wave states comparable to those in the open ocean. Drag parameterizations derived from such experiments (Donelan et al, 2004; Takagaki et al, 2012, 2016; Troitskaya et al, 2012), as well as this study, should be used mindfully and cautiously when implemented into numerical weather prediction models such as WRF (Powers et al, 2017) or Model for Prediction Across Scales (MPAS, Skamarock et al, 2012; Skamarock et al, 2018). This work illustrates that not only are weather and ocean prediction models vulnerable to programmer errors but that the data sets and analyses from which parameterization schemes are derived may contain errors as well.…”

Section: Discussionmentioning

confidence: 89%

“…This parameterization was later used by many (Cavallo et al, 2013; Davis et al, 2008, 2010; Gopalakrishnan et al, 2012; Green & Zhang, 2013, 2014; Nolan et al, 2009). Further, the original data informed and influenced subsequent lines of research (Chen et al, 2007; Chen et al, 2013; Takagaki et al, 2012; Takagaki et al, 2016) and was influential enough to be covered by review papers (Black et al, 2007; Sullivan & McWilliams, 2010). It is thus important to reflect back on the literature since the original publication of the drag saturation data, with the new understanding that the absolute magnitudes of drag coefficient have been underestimated.…”

Section: Correction To Drag and Wind Data By Donelan Et Al (2004)mentioning

confidence: 99%

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Revised Estimates of Ocean Surface Drag in Strong Winds

Curcic

Haus

2020

Geophysical Research Letters

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Air‐sea drag governs the momentum transfer between the atmosphere and the ocean and remains largely unknown in hurricane winds. We revisit the momentum budget and eddy covariance methods to estimate the surface drag coefficient in the laboratory. Our drag estimates agree with field measurements in low‐to‐moderate winds and previous laboratory measurements in hurricane‐force winds. The drag coefficient saturates at 2.6×10−3 and U10≈25 m s−1, in agreement with previous laboratory results by Takagaki et al. (2012,). During our analysis, we discovered an error in the original source code used by Donelan et al. (2004,). We present the corrected data and describe the correction procedure. Although the correction to the data does not change the key finding of drag saturation in strong winds, its magnitude and wind speed threshold are significantly changed. Our findings emphasize the need for an updated and unified drag parameterization based on field and laboratory data.

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Section: Discussionmentioning

confidence: 89%

Section: Correction To Drag and Wind Data By Donelan Et Al (2004)mentioning

confidence: 99%

Revised Estimates of Ocean Surface Drag in Strong Winds

Curcic

Haus

2020

Geophysical Research Letters

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“…) at hurricane wind speeds. As noted by Takagaki et al, 2016, the difference in ! behavior in field and laboratory experiments has not yet been fully clarified.…”

mentioning

confidence: 89%

Correlation between foam-bubble size and drag coefficient in hurricane conditions

Golbraikh

Shtemler

2018

Ocean Dynamics

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Recently proposed model of foam impact on the air-sea drag coefficient ! has been employed for the estimation of the efficient foam-bubble radius ! variation with wind speed !" in hurricane conditions. The model relates ! ( !" ) with the efficient roughness length !"" ( !" ) represented as a sum of aerodynamic roughness lengths of the foam-free and foam-covered sea surfaces ! !" , and ! ( !" ) weighted with the foam coverage coefficient ! ( !" ). This relation is treated for known phenomenological distributions ! ( !" ), ! ( !" ) and ! ( !" ) at strong wind speeds as an inverse problem for the efficient roughness parameter of foam-covered sea surface ! ( !" ).

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“…Accurate estimates of the surface exchange coefficients at high wind speeds have been challenging to obtain in both the laboratory and nature, because of the dangers of collecting in situ observations within the turbulent TC boundary layer. As a result, the surface exchange coefficients are highly uncertain and recent studies often disagree on the sign of the relationship between wind speed and the exchange coefficients (Black et al, 2007;Bell et al, 2012;Chen et al, 2018;Donelan, 2018;Donelan et al, 2004;Holthuijsen et al, 2012;Hsu et al, 2017;Komori et al, 2018;Powell et al, 2003;Troitskaya et al, 2012Troitskaya et al, , 2016Takagaki et al, 2016). Bell et al (2012) attempted to estimate the surface exchange coefficients and suggested that the current uncertainty may be larger than 40%.…”

Section: Citationmentioning

confidence: 99%

Nonlinear Impacts of Surface Exchange Coefficient Uncertainty on Tropical Cyclone Intensity and Air‐Sea Interactions

Nystrom

Chen

Zhang

et al. 2020

Geophysical Research Letters

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Tropical cyclone maximum intensity is believed to result from a balance between the surface friction, which removes energy, and a temperature/moisture (enthalpy) difference between the sea surface and the air above it, which adds energy. The competing processes near the air‐sea interface are controlled by both the near surface wind speed and the surface momentum (Cd) and enthalpy (Ck) exchange coefficients. Unfortunately, these coefficients are currently highly uncertain at high wind speeds. Tropical cyclone winds also apply a force on the ocean surface, which results in ocean surface cooling through vertical mixing. Using coupled atmosphere‐ocean and uncoupled (atmosphere only) ensemble simulations we explore the complex influence of uncertain surface exchange coefficients on storm‐induced ocean feedback and tropical cyclone intensity. We find that the magnitude of ocean cooling increases with storm intensity and Cd. Additionally, the simulated maximum wind speed uncertainty does not necessarily decrease when ocean feedback are considered.

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Mechanism of drag coefficient saturation at strong wind speeds

Cited by 55 publications

References 21 publications

Revised Estimates of Ocean Surface Drag in Strong Winds

Revised Estimates of Ocean Surface Drag in Strong Winds

Correlation between foam-bubble size and drag coefficient in hurricane conditions

Nonlinear Impacts of Surface Exchange Coefficient Uncertainty on Tropical Cyclone Intensity and Air‐Sea Interactions

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