Luca Martinelli scite author profile

Variation in the seasonal and spatial isotopic composition of plant C4 (aquatic macrophytes) and C3 (forest, C3 aquatic macrophytes and algae), and that of fish [Prochilodus nigricans Agassiz, Mylossoma duriventre (Cuvier), Colossoma macropomum (Cuvier), Semaprochilodus insignis (Schomburgk) and S. taeniurus Steindachner in the Amazon floodplain were analysed to test whether the fisheries deliver plant carbon to the population of Manaus in the same proportion as it is available in the floodplain. The contribution of C4 plants was significantly lower in 13C during the season of high water levels and increased toward the west of the basin. Mylossoma duriventre and C. macropomum changed δ13C levels, while the δ13C of P. nigricans and C. macropomum shifted spatially. The contribution of C4 to the fisheries yield was small. C3 plants (excluding phytoplankton) also contributed less than expected. This was explained by the importance of detritivores to the yield of the fisheries and the dependence of these species on algal carbon.

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An approach to assess flooding and erosion risk for open beaches in a changing climate

Villatoro¹,

Silva²,

Méndez³

et al. 2014

Coastal Engineering

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This paper examines the vulnerability to flooding and erosion of four open beach study sites in Europe. A framework for the quantitative estimation of present and future coastal flood and erosion risks is established using methods, data and tools from across a range of disciplines, including topographic and bathymetric data, climate data from observation, hindcast and model projections, statistical modelling of current and future climates and integrated risk analysis tools. Uncertainties in the estimation of future coastal system dynamics are considered, as are the consequences for the inland systems. Different implementations of the framework are applied to the study sites which have different wave, tidal and surge climate conditions. These sites are: Santander, Spain—the Atlantic Ocean; Bellocchio, Italy—the Adriatic Sea; Varna, Bulgaria—the Black Sea; and the Teign Estuary, UK—the northern Atlantic Ocean. The complexity of each system is first simplified by sub-division into coastal “impact units” defined by homogeneity in the local key forcing parameters: wave, wind, tide, river discharge, run-off, etc. This reduces the simulation to that of a number of simpler linear problems which are treated by applying the first two components of the Source–Pathway–Receptor–Consequence (S–P–R–C) approach. The case studies reveal the flexibility of this approach, which is found useful for the rapid assessment of the risks of flooding and erosion for a range of scenarios and the likely effectiveness of flood defences

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Large impulsive forces on recurved parapets under non-breaking waves. A numerical study

Castellino

Sammarco

Romano

et al. 2018

Coastal Engineering

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Assessment of coastal flooding hazard along the Emilia Romagna littoral, IT

Martinelli

Zanuttigh

Corbau

2010

Coastal Engineering

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Sand bag barriers for coastal protection along the Emilia Romagna littoral, Northern Adriatic Sea, Italy

Martinelli

Zanuttigh

Nigris

et al. 2011

Geotextiles and Geomembranes

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Beach nourishments protected by submerged sand bag barriers have been largely used in Emilia Romagna (Italy), whose low and sandy coast faces the relatively mild Northern Adriatic Sea. The paper, after a brief description of the eight projects of this type realised in the last 25 years along the Emilia Romagna littoral, details the case study of Riccione Southern beach. The performance of the defence is described by means of cross-shore profiles, bathymetries, collection of sediment samples, underwater pictures, monitoring of environmental conditions and performed maintenance. The combined analysis of the available data suggests that the sand bag barrier may stabilise the position of the natural sandy bar and ultimately the beach profil

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Experimental investigation on non-breaking wave forces and overtopping at the recurved parapets of vertical breakwaters

Martinelli

Ruol

Volpato

et al. 2018

Coastal Engineering

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Analysis of far-field erosion induced by low-crested rubble-mound structures

Zyserman

Johnson

Zanuttigh

et al. 2005

Coastal Engineering

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Luca Martinelli

Beach response to wave energy converter farms acting as coastal defence

Carbon sources of Amazonian fisheries

An approach to assess flooding and erosion risk for open beaches in a changing climate

Large impulsive forces on recurved parapets under non-breaking waves. A numerical study

Assessment of coastal flooding hazard along the Emilia Romagna littoral, IT

Sand bag barriers for coastal protection along the Emilia Romagna littoral, Northern Adriatic Sea, Italy

Experimental investigation on non-breaking wave forces and overtopping at the recurved parapets of vertical breakwaters

Analysis of far-field erosion induced by low-crested rubble-mound structures

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