More Like this

1. Revisiting wind wave growth with fully coupled direct numerical simulations

   https://doi.org/10.1017/jfm.2022.822  

   Wu, Jiarong; Popinet, Stéphane; Deike, Luc (November 2022, Journal of Fluid Mechanics)

   We investigate wind wave growth by direct numerical simulations solving for the two-phase Navier–Stokes equations. We consider the ratio of the wave speed $$c$$ to the wind friction velocity $$u_*$$ from $$c/u_*= 2$$ to 8, i.e. in the slow to intermediate wave regime; and initial wave steepness $ak$ from 0.1 to 0.3; the two being varied independently. The turbulent wind and the travelling, nearly monochromatic waves are fully coupled without any subgrid-scale models. The wall friction Reynolds number is 720. The novel fully coupled approach captures the simultaneous evolution of the wave amplitude and shape, together with the underwater boundary layer (drift current), up to wave breaking. The wave energy growth computed from the time-dependent surface elevation is in quantitative agreement with that computed from the surface pressure distribution, which confirms the leading role of the pressure forcing for finite amplitude gravity waves. The phase shift and the amplitude of the principal mode of surface pressure distribution are systematically reported, to provide direct evidence for possible wind wave growth theories. Intermittent and localised airflow separation is observed for steep waves with small wave age, but its effect on setting the phase-averaged pressure distribution is not drastically different from that of non-separated sheltering. We find that the wave form drag force is not a strong function of wave age but closely related to wave steepness. In addition, the history of wind wave coupling can affect the wave form drag, due to the wave crest shape and other complex coupling effects. The normalised wave growth rate we obtain agrees with previous studies. We make an effort to clarify various commonly adopted underlying assumptions, and to reconcile the scattering of the data between different previous theoretical, numerical and experimental results, as we revisit this longstanding problem with new numerical evidence. 

   more » « less
2. Vertical Profiles of the Wave-Induced Airflow above Ocean Surface Waves

   https://doi.org/10.1175/JPO-D-18-0121.1  

   Grare, Laurent; Lenain, Luc; Melville, W. Kendall (December 2018, Journal of Physical Oceanography)

   An analysis of coherent measurements of winds and waves from data collected during the ONR Southern California 2013 (SoCal2013) program from R/P FLIP off the coast of Southern California in November 2013 is presented. An array of ultrasonic anemometers mounted on a telescopic mast was deployed to resolve the vertical profile of the modulation of the marine atmospheric boundary layer by the waves. Spectral analysis of the data provides the wave-induced components of the wind velocity for various wind-wave conditions. Results show that the wave-induced fluctuations depend both on the spectral wave age [Formula: see text] and the normalized height [Formula: see text], where c is the linear phase speed of the waves with wavenumber k and [Formula: see text] is the mean wind speed measured at the height z. The dependence on the spectral wave age expresses the sensitivity of the wave-induced airflow to the critical layer where [Formula: see text]. Across the critical layer, there is a significant change of both the amplitude and phase of the wave-induced fluctuations. Below the critical layer, the phase remains constant while the amplitude decays exponentially depending on the normalized height. Accounting for this double dependency, the nondimensionalization of the amplitude of the wave-induced fluctuations by the surface orbital velocity [Formula: see text] collapses all the data measured by the array of sonic anemometers, where a is the amplitude of the waves. 

   more » « less
3. Surface viscous stress over wind-driven waves with intermittent airflow separation

   https://doi.org/10.1017/jfm.2020.760  

   Buckley, M. P.; Veron, F.; Yousefi, K. (December 2020, Journal of Fluid Mechanics)

   The small-scale physics within the first centimetres above the wavy air–sea interface are the gateway for transfers of momentum and scalars between the atmosphere and the ocean. We present an experimental investigation of the surface wind stress over laboratory wind-generated waves. Measurements were performed at the University of Delaware's large wind-wave-current facility using a recently developed state-of-the-art wind-wave imaging system. The system was deployed at a fetch of 22.7 m, with wind speeds from 2.19 to $$16.63\ \textrm {m}\ \textrm {s}^{-1}$$ . Airflow velocity fields were acquired using particle image velocimetry above the wind waves down to $$100\ \mathrm {\mu }\textrm {m}$$ above the surface, and wave profiles were detected using laser-induced fluorescence. The airflow intermittently separates downwind of wave crests, starting at wind speeds as low as $$2.19\ \textrm {m}\ \textrm {s}^{-1}$$ . Such events are accompanied by a dramatic drop in tangential viscous stress past the wave's crest, and a gradual regeneration of the viscous sublayer upon the following (downwind) crest. This contrasts with non-airflow separating waves, where the surface viscous stress drop is less significant. Airflow separation becomes increasingly dominant with increasing wind speed and wave slope $a k$ (where $$a$$ and $$k$$ are peak wave amplitude and wavenumber, respectively). At the highest wind speed ( $$16.63\ \textrm {m}\ \textrm {s}^{-1}$$ ), airflow separation occurs over nearly 100 % of the wave crests. The total air–water momentum flux is partitioned between viscous stress and form drag at the interface. Viscous stress (respectively form drag) dominates at low (respectively high) wave slopes. Tangential viscous forcing makes a minor contribution ( $${\sim }3\,\%$$ ) to wave growth. 

   more » « less
4. Caribbean Easterly Waves: Structure, Thermodynamics, and Instability Mechanisms

   https://doi.org/10.1175/JAS-D-24-0232.1  

   Mayta, Víctor C; Adames_Corraliza, Ángel F; Lin, Qiao-Jun; Vargas_Martes, Rosa M (July 2025, Journal of the Atmospheric Sciences)

   Abstract Caribbean easterly waves (CEWs) propagate in an environment that is distinct from that of other easterly waves since it exhibits substantial westerly vertical wind shear. In spite of this distinction, their structure, propagation, and growth have not received much attention. A linear regression analysis reveals that these systems exhibit features consistent with moisture modes that are destabilized by moisture–vortex instability. They exhibit large moisture fluctuations and are in weak temperature gradient (WTG) balance, and moist static energy (MSE) growth is partly driven by meridional mean MSE advection by the anomalous winds. However, its circulation tilts vertically against the mean shear, a feature that is often associated with baroclinic instability. To reconcile these differences, a linear stability analysis employing a moist two-layer model is performed using a basic state that resembles the Caribbean Sea during boreal summer. The unstable wave solution from this analysis exhibits a structure that resembles observed CEWs. Excluding the upper troposphere from the stability analysis has little impact on the propagation and growth of the wave, and its circulation still exhibits a westward tilt in height. Thus, baroclinic instability is not the main growth mechanism of CEWs despite their structural similarity to baroclinic waves. Instead, the instability is largely rooted in how the lower-tropospheric circulation interacts with water vapor, as expected from moisture mode theory. These results suggest that tilting against the shear should not be used as the sole diagnostic for baroclinic instability. Baroclinic instability is unlikely to be a primary driver of growth for most oceanic tropical-depression-type waves, in agreement with previous work. Significance StatementThe environment in which Caribbean easterly waves propagate has a vertical wind shear that is like that seen in the midlatitudes, with winds becoming more westerly with height. Furthermore, the center of low pressure of the waves shifts toward the west, as in deepening midlatitude weather systems. This wave structure and shear is different from easterly waves that occur in other regions. However, in spite of the similarity to midlatitude weather systems, we show that Caribbean easterly waves mostly grow from moisture transports in the lower atmosphere. Thus, in spite of the distinct environment and wave structure, Caribbean easterly waves are driven by the same processes as other tropical easterly waves. These results underscore the importance of water vapor in driving tropical circulations. They also indicate that the processes that govern the growth of midlatitude weather may be of less importance in the tropics, even in regions that suggest otherwise. 

   more » « less
5. Observations of mean and wave orbital flows in the ocean’s upper centimetres

   https://doi.org/10.1017/jfm.2019.1019  

   Laxague, Nathan J.; Zappa, Christopher J. (March 2020, Journal of Fluid Mechanics)

   Sophisticated measurements of fluid velocity near to an undulating air–water boundary have traditionally been confined to the laboratory setting. Developments in camera technology and the opening of novel modes of analysis have allowed for sensitive measurements of the current profile in the ocean’s uppermost layer. Taking advantage of the Research Platform R/P FLIP as a ‘laboratory at sea’, here we present first-of-their-kind thermal and polarimetric camera-based observations of wave orbital velocities and mean shear flows in the upper centimetres of the ocean surface layer. Measurements reveal a well-defined logarithmic layer as seen in laboratory measurements and described by classical surface layer theory; however, substantial spread of observations is found at low levels of wind forcing, where the Stokes drift of swell may have a substantial impact on the near-surface current profile. A novel application of short time window Fourier transforms allows for the estimation of near-surface wave orbital velocity magnitudes. These are found to be in general agreement with the prescriptions of linear wave theory, although observations diverge from theory at high levels of wind forcing where the interface is subject to surface wave breaking. Finally, the surface gravity wave phase-coherent short wave growth is presented and discussed in the context of hydrodynamic wave and airflow modulation. 

   more » « less