Characterization of Wind-Sea- and Swell-Induced Wave Energy along the Norwegian Coast

Konstantinos Christakos,George Varlas,Birgitte Rugaard Furevik,Ioannis Cheliotis,Christos Spyrou,Ole Johan Aarnes

doi:10.3390/atmos11020166

Abstract

The necessity to reduce C O 2 emissions in combination with the rising energy demand worldwide makes the extensive use of renewable energy sources increasingly important. To that end, countries with long coastlines, such as Norway, can exploit ocean wave energy to produce large amounts of power. In order to facilitate these efforts as well as to provide quantitative data on the wave energy potential of a specific area, it is essential to analyze the weather and climatic conditions detecting any variabilities. The complex physical processes and the atmosphere-wave synergetic effects make the investigation of temporal variability of wave energy a challenging issue. This work aims to shed new light on potential wave energy mapping, presenting a spatio-temporal assessment of swell- and wind-sea-induced energy flux in the Nordic Seas with a focus on the Norwegian coastline using the NORA10 hindcast for the period 1958–2017 (59 years). The results indicate high spatial and seasonal variability of the wave energy flux along the coast. The maximum wave energy flux is observed during winter, while the minimum is observed during summer. The highest coastal wave energy flux is observed in the Norwegian Sea. The majority of areas with dominant swell conditions (i.e., in the Norwegian Sea) are characterized by the highest coastal wave energy flux. The maximum values of wave energy flux in the North Sea are denoted in its northern parts in the intersection with the Norwegian Sea. In contrast to the Norwegian Sea, areas located in the North Sea and the Barents Sea show that wind sea is contributing more than swell to the total wave energy flux.

Highlights

According to the European long-term strategy [1], Europe needs to maximize the deployment of renewables aiming to fully decarbonize its energy supply
The spatial variation of the average Hs, Tp, and Wave Energy Flux (WEF) values is shown in Figure 2 for NORA10 domain covering the Northeast Atlantic Ocean including the Nordic Seas i.e., the North Sea, the Norwegian Sea, and the Barents Sea
The highest values of WEF in the North Sea are observed in its northern region due to the exposure to swell propagated through the Norwegian Sea, which is indicated in the study of Lavidas and Polinder [48]

Summary

Introduction

According to the European long-term strategy [1], Europe needs to maximize the deployment of renewables aiming to fully decarbonize its energy supply. Resources such as wind, tidal currents, and waves could play a key role in the decarbonization of electricity production around the world [2]. There are many offshore areas characterized by considerably high marine energy supply, due to intense winds, increased tidal activity, and high waves [3]. The oceans offer a vast amount of renewable energy that is currently unexploited. The accurate estimation of the MRE potential is fundamental in harnessing ocean energy

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