Strong mode-mode interactions in internal solitary-like waves

Stastna, Marek; Olsthoorn, Jason; Baglaenko, Anton; Coutino, Aaron

doi:10.1063/1.4919115

Cited by 12 publications

(25 citation statements)

References 30 publications

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“…Similar to the case 1, the characteristics and energy loss of the amplitude-modulated wave packet for the case 5 were also similar with the breather definition. Noted that the breather solution exist only if the cubic nonlinearity coefficients in Gardner equation is positive (Lamb et al, 2007), but the configuration of the stratification in our simulation results a negative cubic nonlinearity coefficient in Gardner equation (Grimshaw et al, 2010;Talipova et al, 2011) and it means the breather is not allowed The oscillating tail was frequently observed in similar studies (Carr et al, 2015;Olsthoorn et al, 2013;Stastna et al, 2015). Its generation was related to the shear, and the tail was sustained by continuous energy input.…”

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confidence: 60%

The evolution of mode-2 internal solitary waves modulated by background shear currents

Zhang¹,

Xu²,

Qun³

et al. 2018

Preprint

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Abstract. The evolution process of mode-2 internal solitary waves (ISWs) modulated by the background shear currents was investigated numerically. The forward-propagating long wave, amplitude-modulated wave packet were generated during the early stage of modulation, where the amplitude-modulated wave packet were suggested playing an important role in the energy transfer 15 process, and then the oscillating tail was generated and followed the solitary wave. Five different cases were introduced to assess the sensitivity of the energy transfer process to the Δ, which defined as a dimensionless distance between the centers of pycnocline and shear current. The forward-propagating long waves were found robust to the Δ, but the oscillating tail and amplitude-modulated wave packet decreased in amplitude with increasing Δ. The highest energy loss rate was observed when Δ = 0. In the 20 first 30 periods, ~36% of the total energy lost at an average rate of 9 W m -1 , it would deplete the energy of the solitary wave in ~4.5 h, corresponding to a propagation distance of ~5 km, which is consistent with the hypothesis of Shroyer et al. (2010), who speculated that the mode-2 ISWs are "short-lived" in the presence of shear currents.

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confidence: 60%

The evolution of mode-2 internal solitary waves modulated by background shear currents

Zhang¹,

Xu²,

Qun³

et al. 2018

Preprint

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“…The effect of the Earth's rotation is neglected, and hence the simulations are performed in an inertial frame of reference. A complete description of the numerical model used in this study can be found in Subich et al (2013), where a detailed validation and accuracy analysis through several test cases is also given. The model employs a spectral collocation method, which yields highly accurate results at moderate grid resolutions.…”

Section: Governing Equations and Numerical Methodsmentioning

confidence: 99%

“…The interaction between internal waves of different length scales also occurs naturally (Sun and Pinkel, 2012). When the disparity in length scales between the participating waves is large, the relatively smaller length scale wave essentially plays the role of the disturbance to the "background flow" 2 C. Xu and M. Stastna: ISW-short wave interaction induced by the relatively larger length scale wave, as they interact with each other.…”

Section: Introductionmentioning

confidence: 99%

“…A key finding is that for waves that are short in comparison to the ISW width, the interaction leads to an almost complete destruction of the short waves; for mode-1 short waves, however, there is a cutoff determined by the wavelength of short waves, and waves longer than this cutoff maintain their structure after interaction. We show that this is a key difference from mode-1-mode-2 interaction, which is examined in Stastna et al (2015). The energy transfer during the interaction is discussed in Sect.…”

Section: Introductionmentioning

confidence: 99%

“…investigated the interaction between two mode-1 internal solitary waves (ISWs), and showed that the interaction of solitary waves did not correspond to soliton dynamics, since energy exchange was observed and small-amplitude trailing waves of possibly higher modes were generated. More recently, Stastna et al (2015) examined the interaction between mode-1 and mode-2 internal solitary (solitary-like in cases when the mode-2 wave was breaking) waves, and demonstrated that the interaction yielded a nearly complete disintegration of the relatively smaller mode-2 wave. In particular, the majority of kinetic energy carried by the mode-2 wave was lost and the disturbance to the flow field after the collision no longer had a mode-2 structure.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

On the interaction of short linear internal waves with internal solitary waves

Stastna

2018

Nonlin. Processes Geophys.

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Abstract. We study the interaction of small-scale internal wave packets with a large-scale internal solitary wave using high-resolution direct numerical simulations in two dimensions. A key finding is that for wave packets whose constituent waves are short in comparison to the solitary wave width, the interaction leads to an almost complete destruction of the short waves. For mode-1 short waves in the packet, as the wavelength increases, a cutoff is reached, and for larger wavelengths the waves in the packet are able to maintain their structure after the interaction. This cutoff corresponds to the wavelength at which the phase speed of the short waves upstream of the solitary wave exceeds the maximum current induced by the solitary wave. For mode-2 waves in the packet, however, no corresponding cutoff is found. Analysis based on linear theory suggests that the destruction of short waves occurs primarily due to the velocity shear induced by the solitary wave, which alters the vertical structure of the waves so that significant wave activity is found only above (below) the deformed pycnocline for overtaking (head-on) collisions. The deformation of vertical structure is more significant for waves with a smaller wavelength. Consequently, it is more difficult for these waves to adjust to the new solitary-waveinduced background environment. These results suggest that through the interaction with relatively smaller length scale waves, internal solitary waves can provide a means to decrease the power observed in the short-wave band in the coastal ocean.

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Internal solitary wave generation by the tidal flows beneath ice keel in the Arctic Ocean

Zhang

et al. 2022

J. Ocean. Limnol.

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Strong mode-mode interactions in internal solitary-like waves

Cited by 12 publications

References 30 publications

The evolution of mode-2 internal solitary waves modulated by background shear currents

The evolution of mode-2 internal solitary waves modulated by background shear currents

On the interaction of short linear internal waves with internal solitary waves

Internal solitary wave generation by the tidal flows beneath ice keel in the Arctic Ocean

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