/2/m_15515036-70_sp1_cover.jpeg?Expires=1716905414&Signature=i3yNO3ruYTTXctnH-5Uu7nlMnW28rrnOrxSe4kDsYnKxDWmfPLbstiqTE29zIsneeI9j8fymC8W7JHuca3as2w57erzkhq3oXURnI6ONQCUJ1Eq6thNzOcGZ6CNWto280lpUPoDN-YRTaYsQvAczUMMifs~HAMkRYC~tk7eIBusXq-5inwD7j2h8VzPWGoqDm1EWmJiJb5XM-EqDGj1fjQjWIfUj~Q5tVej8bEhgSOB9Awqz3eP7wvAdYMINe2zo~wI8CKfmQyIpyUj87bKKmaYWfri92i6nAK2ZEt-Nash-QZt7ygFQJi~xfRbkS96vuQO0icsMLvLji1HDajvcew__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA)
ABSTRACT
Villagran M., Caamaño D., Cienfuegos R., 2014. Hydrodynamics of a river-associated tidal inlet and maintenance of dynamic equilibrium: preliminary findings. In: Green, A.N. and Cooper, J.A.G. (eds.), Proceedings 13th International Coastal Symposium (Durban, South Africa), Journal of Coastal Research, Special Issue No. 70, pp. 592–597, ISSN 0749-0208.
Detailed video images and ADCP measurements were used to describe the processes of suspended sediment transport by the Mataquito River into the Pacific Ocean. It is found that, in the absence of fluvial flood discharges, suspended sediment transport to the sea only takes place during low tide periods and it is characterized by pulses of different frequencies that in turn are related to the spatial velocity distribution at the river inlet. It was observed that at low tide the highest velocities are near the mouth of the river, presenting an heterogeneous spatial distribution. In this high speed zone, we hypothesized the shear stresses are big enough to re-suspend fine sediment that is transported into the ocean by the main river current. A simple conceptual explanation based on these findings is presented, seeking to explain the observed dynamic equilibrium of the Mataquito River inlet after the significant alterations produced by the 2010 M8.8 earthquake and tsunami.
