Direct measurements reveal instabilities and turbulence within large amplitude internal solitary waves beneath the ocean

Internal solitary waves are ubiquitous in coastal regions and marginal seas of the world's oceans. As the waves shoal shoreward, they lose the energy obtained from ocean tides through globally significant turbulent mixing and dissipation and consequently pump nutrient-rich water to nourish coastal ecosystem. Here we present fine-scale, direct measurements of shoaling internal solitary waves in the South China Sea, which allow for an examination of the physical processes triggering the intensive turbulent mixing in their interior. These are convective breaking in the wave core and the collapse of Kelvin-Helmholtz billows in the wave rear and lower periphery of the core, often occurring simultaneously. The former takes place when the particle velocity exceeds the wave's propagating velocity. The latter is caused by the instability induced by the strong velocity shear overcoming the stratification. The instabilities generate turbulence levels four orders of magnitude larger than that in the open ocean.

Ming-Huei Chang, Yu-Hsin Cheng, Yiing Jang Yang, Sen Jan, Steven R. Ramp, D. Benjamin Reeder, Wan-Ting Hsieh, Dong S. Ko, Kristen A. Davis, Huan-Jie Shao, Ruo-Shan Tseng