Abstract
The ocean contains a variety of renewable energy resources, little of which has been exploited. Here, we review both tidal range and tidal stream energy, with a focus on the resource, feedbacks, and environmental interactions. The review covers a wide range of timescales of relevance to tidal energy, from fortnightly (spring-neap) and semi-diurnal variability, down to array, and device-scale turbulence. When simulating the regional tidal energy resource, and to assess environmental impacts, it is necessary to account for feedbacks between the tidal array and the resource itself. We critically review various methods for simulating energy extraction, from insights gained through theoretical studies of “tidal fences” in idealized channels, to realistic three-dimensional model studies with complex geometry and arrays of turbines represented by momentum sinks and additional turbulence due to the presence of rotors and support structures. We discuss how variability can be reduced by developing multiple (aggregated) sites with a consideration of the enhanced phase diversity offered by exploiting less energetic tidal currents. This leads to future research questions that have not yet been explored in depth at first-generation tidal sites in relatively sheltered channels (e.g., the interaction of waves with currents). Such enhanced understanding of real sea conditions, including the effects of wind and waves, leads to our other identified primary future research direction—reduced uncertainties in turbulence predictions, including the development of realistic models that simulate the interaction between ambient turbulence and the turbulence resulting from multiple wakes, and changes to system-wide hydrodynamics, water quality, and sedimentation.
Highlights
Investment in emerging renewable energy technologies is essential if the global energy sector is to transition from fossil-based towards zero-carbon by the second half of this century, limiting the impacts of climate change1
Global tidal dissipation is around 2.4 TW, with the majority of this, 1.7 TW, occurring in shelf sea environments6. This represents an upper theoretical bound for tidal power, but due to interaction between tidal energy extraction and the resource7, in addition to technical and practical constraints, the available resource is likely to be considerably less
Goh et al.140 613 investigated the effect of tidal energy extraction on flow field and sediment erosion adjacent to headlands along Negeri Sembilan (Malaysia) coastlines using numerical modeling
Summary
Investment in emerging renewable energy technologies is essential if the global energy sector is to transition from fossil-based towards zero-carbon by the second half of this century, limiting the impacts of climate change. Global tidal dissipation is around 2.4 TW, with the majority of this, 1.7 TW, occurring in shelf sea environments6 This represents an upper theoretical bound for tidal power, but due to interaction between tidal energy extraction and the resource, in addition to technical and practical constraints, the available resource is likely to be considerably less. To put this in perspective, annual mean global electricity consumption is around 3 TW8, and so even if 10% of the shelf sea resource was exploited, i.e. 170 GW, tidal energy could have a substantial contribution to 61 the global energy mix. We identify future research areas that need to be addressed before the tidal energy resource can be exploited to its full potential
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