Your search keyword '"Andrea Cucco"' showing total 2 results

1. M2, overtides and compound tides generation in the Strait of Messina: the response of a non-hydrostatic, finite-element ocean model

Author

Giovanni Quattrocchi, Matthew D. Piggott, Gerard J. Gorman, and Andrea Cucco

Subjects

010504 meteorology & atmospheric sciences, Ecology, 010505 oceanography, Model domain, Elevation, Non hydrostatic, 01 natural sciences, Finite element method, Oceanography, Mediterranean sea, Barotropic fluid, Unstructured mesh, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Water Science and Technology

Abstract

Quattrocchi, A.; Gorman, J.G., Piggott M.D. and Cucco, A., 2016. M2, overtides and compound tides generation in the Strait of Messina: the response of a non-hydrostatic, finite-element ocean model. In: Vila-Concejo, A.; Bruce, E.; Kennedy, D.M., and McCarroll, R.J. (eds.), Proceedings of the 14th International Coastal Symposium (Sydney, Australia). Journal of Coastal Research, Special Issue, No. 75, pp. 657–661. Coconut Creek (Florida), ISSN 0749-0208. The nonlinear interactions between the main tidal constituents and geographical constraints are investigated using Fluidity-ICOM, a non-hydrostatic finite-element ocean model that was implemented in the region of the Strait of Messina (Mediterranean Sea). As a first crucial approach, the barotropic tidal dynamics was investigated and the model solution was interpreted in terms of tidal maps and spectra obtained by harmonic analysis of the sea surface elevation. The model domain is represented by an unstructured mesh with variable spatial resolution...

Published

2016

2. Morphological changes of a Mediterranean beach over one year (San Giovanni Sinis, western Mediterranean)

Author

Simone Simeone, Giovanni De Falco, Giovanni Quattrocchi, and Andrea Cucco

Subjects

Mediterranean climate, Coastal hazards, Ecology, Storm, beach morphology, beach profile, Oceanography, Geography, Subaerial, Period (geology), storms, numerical model, Earth-Surface Processes, Water Science and Technology

Abstract

Mediterranean beaches experience major modifications in their morphology and grain size features mainly during intense storms and extreme meteo-marine events. The assessment of beach response to storms can be useful in the evaluation of coastal hazards, and in relation to the efficiency of management projects such as artificial nourishment. This paper aims to establish the subaerial morphological response of a beach located in western Sardinia (western Mediterranean) during the period of a year. Both experimental and numerical approaches were adopted to investigate the beach system. In particular, beach profiles, acquired by means of Differential Positioning System were used to analyze the morphological changes of the beach and wave parameters and current velocity data were collected by means of an Acoustic wave and current meter (ADCP). Numerical techniques were also applied to investigate the hydrodynamics in the area of study. Coupled wind wave - 3D hydrodynamic finite element model were used to reproduce the wave propagation and the wind, tide and wave induced 3D water circulation along the coastal areas, and it displayed a good accuracy. During the year, the beach experienced intense morphological changes in the area where submerged beach is not occupied by rocky outcrops and the model was also able to reproduce the related observed periods of strong wind wave events. The interdisciplinary approach allowed an evaluation to be made about the response of the beach morphology in respect to meteo-marine forcings.

Published

2014