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Marine Industry: Offshore Renewable Energy

• Reviews
• Development and Prospects
• Public Opinion and Engagement
• Policy and Legal Issues
• Environmental Impacts

Reviews

• Moriarty, P. and Honnery, D.  What is the global potential for renewable energy?  Renewable and Sustainable Energy Reviews 16(1): 244-252, 2012.  
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  World energy demand is projected to rise to 1000 EJ (EJ = 10(18) J) or more by 2050 if economic growth continues its course of recent decades. Both reserve depletion and greenhouse gas emissions will necessitate a major shift from fossil fuels as the dominant energy source. Since nuclear power is now unlikely to increase its present modest share, renewable energy (RE) will have to provide for most energy in the future. This paper addresses the questions of what energy levels RE can eventually provide, and in what time frame. We find that when the energy costs of energy are considered, it is unlikely that RE can provide anywhere near a 1000 EJ by 2050. We further show that the overall technical potential for RE will fall if climate change continues. We conclude that the global shift to RE will have to be accompanied by large reductions in overall energy use for environmental sustainability.

• Bahaj, A.B.S.  Generating electricity from the oceans.  Renewable and Sustainable Energy Reviews 15(7): 3399-3416, 2011.
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  Ocean energy has many forms, encompassing tides, surface waves, ocean circulation, salinity and thermal gradients. This paper will considers two of these, namely those found in the kinetic energy resource in tidal streams or marine currents, driven by gravitational effects, and the resources in wind-driven waves, derived ultimately from solar energy. There is growing interest around the world in the utilisation of wave energy and marine currents (tidal stream) for the generation of electrical power. Marine currents are predictable and could be utilised without the need for barrages and the impounding of water, whilst wave energy is inherently less predictable, being a consequence of wind energy. The conversion of these resources into sustainable electrical power offers immense opportunities to nations endowed with such resources and this work is partially aimed at addressing such prospects. The research presented conveys the current status of wave and marine current energy conversion technologies addressing issues related to their infancy (only a handful being at the commercial prototype stage) as compared to others such offshore wind. The work establishes a step-by-step approach that could be used in technology and project development, depicting results based on experimental and field observations on device fundamentals, modelling approaches, project development issues. It includes analysis of the various pathways and approaches needed for technology and device or converter deployment issues. As most technology developments are currently UK based, the paper also discusses the UK's financial mechanisms available to support this area of renewable energy, highlighting the needed economic approaches in technology development phases. Examination of future prospects for wave and marine current ocean energy technologies are also discussed.

Development and Prospects

• Esteban, M.D., Diez, J.J., López, J.S., and Negro, V.  Why offshore wind energy?  Renewable Energy 36(2): 444-450, 2011.  
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  At the beginning of 2010, only 2000 wind megawatts had been installed offshore. Although the first offshore wind farm experiment took place in 1990, most of the facilities built up to now have been pilot projects. Then, offshore wind power can be considered as an incipient market. However, just at this moment, the growth of this technology finally seems to be happening, being several countries at the top of its development (the United Kingdom, Denmark, Holland, Sweden and Germany). This current situation, the raw materials problems and the general commitments to reduce the emissions of greenhouse gases are leading to predict a promising future for this technology. This paper deals with a brief revision of the state of the art of offshore wind power, followed by a critical discussion about the causes of the recent growth that is currently happening. The discussion is based on the comparison of offshore wind energy with other renewable energies (like onshore wind, marine hydrodynamics, hydraulic, solar, etc.) and even with conventional power.

• Kaldellis, J.K. and Zafirakis, D.  The wind energy (r)evolution: A short review of a long history.  Renewable Energy 36(7): 1887-1901, 2011.
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  Although wind energy exploitation dates back five thousand years ago, contemporary societies are based almost exclusively on fossil fuels for covering their electrical energy needs. On the other hand, during the last thirty years, security of energy supply and environmental issues have reheated the interest for wind energy applications. In this context, the present work traces the long and difficult steps of wind energy development from the California era to the construction of huge offshore wind parks worldwide, highlighting the prospects and the main challenges of wind energy applications towards the target of 1000GW of wind power by 2030.

• Esteban, M. and Leary, D.  Current developments and future prospects of offshore wind and ocean energy.  Applied Energy 90(1): 128-136, 2011.   
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  The year 2008 saw the emergence of the first generation of commercial ocean energy devices, with the first units being installed in the UK and Portugal. This means that there are currently four ways of obtaining energy from sea areas, namely from wind, tides, waves and thermal differences between deep and shallow sea water. This paper focuses on current developments in offshore wind and ocean energy, highlighting the efforts currently underway in a variety of countries, principally some of the projects typically less talked about such as those in the Asian-Pacific countries. Finally, the growth potential of these industries will be assessed, using as a basis the historical trends in the offshore wind industry and extrapolating it to compute future growth potentials. Using this as a basis, the percentage of the world's electricity that could be produced from ocean based devices is estimated to be around 7% by 2050, and this would employ a significant amount of people by this time, possibly around 1 million, mostly in the maintenance of existing installations. The paper will also evaluate the likely cost of production per kW of ocean energy technologies using a variety of learning factors.

• Leary, D. and Esteban, M.  Recent developments in offshore renewable energy in the Asia-Pacific region.  Ocean Development and International Law 42(1-2): 94-119, 2011.
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  This article examines the emergence of offshore renewable energy (i.e., offshore wind, ocean, and tidal energy) in the Asia-Pacific region with a particular focus on developments in China, South Korea, Australia, and New Zealand. It outlines plans for the development of offshore wind, tidal, and wave energy projects as well as emerging legal and policy measures supporting the growth of offshore renewable energy in the region. The article highlights that, although some progress has been made on laws and other measures to facilitate offshore renewable energy in the Asia-Pacific region, clear regulatory frameworks are still emerging in these jurisdictions.

• Wang, S., Yuan, P., Li, D., and Jiao, Y.  An overview of ocean renewable energy in China.  Renewable and Sustainable Energy Reviews 15(1): 91-111, 2011.
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  Facing great pressure of economic growth and energy crisis, China pays much attention to the renewable energy. An overview of policy and legislation of renewable energy as well as status of development of renewable energy in China was given in this article. By analysis, the authors believe that ocean energy is a necessary addition to existent renewable energy to meet the energy demand of the areas and islands where traditional forms of energy are not applicable and it is of great importance in adjusting energy structure of China. In the article, resources distribution and technology status of tidal energy, wave energy, marine current energy, ocean thermal energy and salinity gradient energy in China was reviewed, and assessment and advices were given for each category. Some suggestions for future development of ocean energy were also given.

• Bilgili, M., Yasar, A., and Simsek, E.  Offshore wind power development in Europe and its comparison with onshore counterpart.  Renewable and Sustainable Energy Reviews 15(2): 905-915, 2011.
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  Wind power, as a renewable source of energy, produces no emissions and is an excellent alternative in environmental terms to conventional electricity production based on fuels such as oil, coal or natural gas. At present, the vast majority of wind power is generated from onshore wind farms. However, their growth is limited by the lack of inexpensive land near major population centers and the visual pollution caused by large wind turbines. Comparing with onshore wind power, offshore winds tend to flow at higher speeds than onshore winds, thus it allows turbines to produce more electricity. Estimates predict a huge increase in wind energy development over the next 20 years. Much of this development will be offshore wind energy. This implies that great investment will be done in offshore wind farms over the next decades. For this reason, offshore wind farms promise to become an important source of energy in the near future. In this study, history, current status, investment cost, employment, industry and installation of offshore wind energy in Europe are investigated in detail, and also compared to its onshore counterpart.

• Toke, D.  The UK offshore wind power programme: A sea-change in UK energy policy?  Energy Policy 39(2): 526-534, 2011.
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  The British offshore windfarm programme presages the emergence of Britain as more of a leader than a laggard in renewables, the latter being the status it has hitherto endured in comparison to countries such as Denmark, Germany and Spain. Britain looks increasingly likely to exceed 20% of electricity being supplied from renewable energy by 2020, provided there continues to be adequate financial incentives for renewable energy. This turnaround is associated with increased British concerns about energy dependence on imported natural gas as well as pressure from EU legislation. However there are many planning pressures that countervail the drive for offshore wind power. British planning policy on offshore wind is distinctive (compared to other EU states) for its pragmatic, 'criteria based', approach that appears to favour offshore wind power development. The extent of the British offshore wind power programme is likely to depend heavily on consumer reactions to price increases caused by the offshore wind power programme.

• Jay, S.  Mobilising for marine wind energy in the United Kingdom.  Energy Policy 39(7): 4125-4133, 2011.
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  Since 2000, the United Kingdom has enthusiastically adopted marine wind energy as a potentially major source of electricity production and has become the leading nation in terms of output. This is in contrast to its relatively poor attainment of wind energy on land, and raises questions about the reasons for this difference in performance. This article traces the phases of development of marine wind energy in the UK with reference to factors that are instrumental in the uptake of this form of renewable energy. A number of features emerge from this analysis that stand in some contrast to the situation on land and help to explain the UK's current status. These include: recognition of an exceptional resource and relative ease of exploitation; government commitment and policy geared to controlled growth and strategic oversight, adequate economic support and start-up investment; the unusual rights and interests of the Crown Estate; and growing scale, confidence and organisation on the part of the industry. Set against these factors are the complexities of consenting, supply bottlenecks, and some stakeholder and public resistance, though these are outmatched by the drivers in favour of development and are being partly addressed.

• Faizal, M. and Rafiuddin, A.M.  On the ocean heat budget and ocean thermal energy conversion.  International Journal of Energy Research 35(13): 1119-1144, 2011.
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  Ocean water covers a vast portion of the Earth's surface and is also the world's largest solar energy collector. It plays an important role in maintaining the global energy balance as well as in preventing the Earth's surface from continually heating up because of solar radiation. The ocean also plays an important role in driving the atmospheric processes. The heat exchange processes across the ocean surface are represented in an ocean thermal energy budget, which is important because the ocean stores and releases thermal energy. The solar energy absorbed by the ocean heats up the surface water, despite the loss of heat energy from the surface due to back-radiation, evaporation, conduction, and convection, and the seasonal change in the surface water temperature is less in the tropics. The cold water from the higher latitudes is carried by ocean currents along the ocean bottom from the poles towards the equator, displacing the lower-density water above and creating a thermal structure with a large reservoir of warm water at the ocean surface and a large reservoir of cold water at the bottom, with a temperature difference of 22 ºC to 25 ºC between them. The available thermal energy, which is the almost constant temperature water at the beginning and end of the thermocline, in some areas of the oceans, is suitable to drive ocean thermal energy conversion (OTEC) plants. These plants are basically heat engines that use the temperature difference between the surface and deep ocean water to drive turbines to generate electricity. A detailed heat energy budget of the ocean is presented in the paper taking into consideration all the major heat inputs and outputs. The basic OTEC systems are also presented and analyzed in this paper.

• Fujita, R., Markham, A.C., Diaz Diaz, J.E., Martinez Garcia, J.R., Scarborough, C., Greenfield, P., Black, P., and Aguilera, S.E.  Revisiting ocean thermal energy conversion.  Marine Policy 36(2): 463-465, 2012.
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  Increasing concerns regarding oil spills, air pollution, and climate change associated with fossil fuel use have increased the urgency of the search for renewable, clean sources of energy. This assessment describes the potential of Ocean Thermal Energy Conversion (OTEC) to produce not only clean energy but also potable water, refrigeration, and aquaculture products. Higher oil prices and recent technical advances have improved the economic and technical viability of OTEC, perhaps making this technology more attractive and feasible than in the past. Relatively high capital costs associated with OTEC may require the integration of energy, food, and water production security in small island developing states (SIDSs) to improve cost-effectiveness. Successful implementation of OTEC at scale will require the application of insights and analytical methods from economics, technology, materials engineering, marine ecology, and other disciplines as well as a subsidized demonstration plant to provide operational data at near-commercial scales.

• Heath, T.V.  A review of oscillating water columns.  Philosophical Transactions of the Royal Society of London [A] 370(1959): 235-245, 2012.
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  This paper considers the history of oscillating water column (OWC) systems from whistling buoys to grid-connected power generation systems. The power conversion from the wave resource through to electricity via pneumatic and shaft power is discussed in general terms and with specific reference to Voith Hydro Wavegen's land installed marine energy transformer (LIMPET) plant on the Scottish island of Islay and OWC breakwater systems. A report on the progress of other OWC systems and power take-off units under commercial development is given, and the particular challenges faced by OWC developers reviewed.

• Whittaker, T. and Folley, M.  Nearshore oscillating wave surge converters and the development of Oyster.  Philosophical Transactions of the Royal Society of London [A] 370(1959): 345-364, 2012.
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  Oscillating wave surge converters (OWSCs) are a class of wave power technology that exploits the enhanced horizontal fluid particle movement of waves in the nearshore coastal zone with water depths of 10-20 m. OWSCs predominantly oscillate horizontally in surge as opposed to the majority of wave devices, which oscillate vertically in heave and usually are deployed in deeper water. The characteristics of the nearshore wave resource are described along with the hydrodynamics of OWSCs. The variables in the OWSC design space are discussed together with a presentation of some of their effects on capture width, frequency bandwidth response and power take-off characteristics. There are notable differences between the different OWSCs under development worldwide, and these are highlighted. The final section of the paper describes Aquamarine Power's 315 kW Oyster 1 prototype, which was deployed at the European Marine Energy Centre in August 2009. Its place in the OWSC design space is described along with the practical experience gained. This has led to the design of Oyster 2, which was deployed in August 2011. It is concluded that nearshore OWSCs are serious contenders in the mix of wave power technologies. The nearshore wave climate has a narrower directional spread than the offshore, the largest waves are filtered out and the exploitable resource is typically only 10-20% less in 10 m depth compared with 50 m depth. Regarding the devices, a key conclusion is that OWSCs such as Oyster primarily respond in the working frequency range to the horizontal fluid acceleration; Oyster is not a drag device responding to horizontal fluid velocity. The hydrodynamics of Oyster is dominated by inertia with added inertia being a very significant contributor. It is unlikely that individual flap modules will exceed 1 MW in installed capacity owing to wave resource, hydrodynamic and economic constraints. Generating stations will be made up of line arrays of flaps with communal secondary power conversion every 5-10 units.

• Rainey, R.C.T.  Key features of wave energy.  Philosophical Transactions of the Royal Society of London [A] 370(1959): 425-438, 2012.
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  For a weak point source or dipole, or a small body operating as either, we show that the power from a wave energy converter (WEC) is the product of the particle velocity in the waves, and the wave force (suitably defined). There is a thus a strong analogy with a wind or tidal turbine, where the power is the product of the fluid velocity through the turbine, and the force on it. As a first approximation, the cost of a structure is controlled by the force it has to carry, which governs its strength, and the distance it has to be carried, which governs its size. Thus, WECs are at a disadvantage compared with wind and tidal turbines because the fluid velocities are lower, and hence the forces are higher. On the other hand, the distances involved are lower. As with turbines, the implication is also that a WEC must make the most of its force-carrying ability—ideally, to carry its maximum force all the time, the '100% sweating WEC'. It must be able to limit the wave force on it in larger waves, ultimately becoming near-transparent to them in the survival condition—just like a turbine in extreme conditions, which can stop and feather its blades. A turbine of any force rating can achieve its maximum force in low wind speeds, if its diameter is sufficiently large. This is not possible with a simple monopole or dipole WEC, however, because of the 'nλ/2 π' capture width limits. To achieve reasonable 'sweating' in typical wave climates, the force is limited to about 1?MN for a monopole device, or 2 MN for a dipole. The conclusion is that the future of wave energy is in devices that are not simple monopoles or dipoles, but multi-body devices or other shapes equivalent to arrays.

• Garrad, A.  The lessons learned from the development of the wind energy industry that might be applied to marine industry renewables.  Philosophical Transactions of the Royal Society of London [A] 370(1959): 451-471, 2012.
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  This paper considers the early experiences of the development of wind turbines and the wind energy industry in order to try and identify lessons learned that could now be applied to the developing marine renewables technology and industry. It considers both political and commercial incentives and engineering development.

• Colander, B. and Monroe, L.  Offshore renewable energy: the path forward.  Electricity Journal 24(7): 23-34, 2011.
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  Proponents have espoused the potential for offshore renewable energy generation for many years, but to-date there are still no commercial projects in U.S. waters. Some of the lessons learned from the struggle of offshore renewable energy to gain a foothold involve the siting of renewables as well as navigation of the regulatory framework.

Public Opinion and Engagement

• Haggett, C.  Understanding public responses to offshore wind power.  Energy Policy 39(2): 503-510, 2011.  
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  This paper is about understanding the role and importance of public responses to offshore wind power. It builds on a framework for understanding social acceptance and opposition to onshore turbines, and reviews the emerging research on offshore wind. While less is known about how people will respond to offshore than onshore wind, there is now an emerging body of research. From this literature, several common factors which influence responses have emerged and are discussed here: the (continued) role of visual impact; place attachment to the local area; lack of tangible benefits; relationships with developers and outsiders; and the role of the planning and decision-making systems. The paper argues that, as with onshore developments, the public should be included in decision-making about offshore wind farms, and that they have a key role which should not be underestimated. The paper concludes with some thoughts about the means to involve people and how effected communities might be effectively acknowledged, identified and engaged.

• Todt, O., González, M.I., and Estévez, B.  Conflict in the Sea of Trafalgar: offshore wind energy and its context.  Wind Energy 14(5): 699-706, 2011.
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  This paper analyses a participatory process related to the plan to construct an offshore wind farm in the Sea of Trafalgar, off the coast of Cádiz, in Andalucía (southern Spain). This case study shows the complexities of public participation in energy development, indicating the vital importance of context. The stakeholders' values and attitudes in the controversy are highly dependent on the specific situation, including the concrete characteristics of the project proposal. In fact, they may diverge sharply from the stakeholders' core beliefs. It is important for decision making to take account of this contextual and dynamic element in stakeholder behavior, contrary to suppositions of static and predetermined behavior.

• Bailey, I., West, J., and Whitehead, I.  Out of sight but not out of mind? Public perceptions of wave energy.  Journal of Environmental Policy and Planning 13(2): 139-157, 2011.   
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  Public concern about the visual and environmental impacts of renewable energy projects has been a major factor behind the stalling or rejection of many planning applications for on-shore renewables developments. Siting renewables facilities in off-shore locations would appear to reduce this tension but, as yet, limited research has been conducted on public attitudes to marine renewables -- particularly tidal and wave power -- to establish how genuinely 'out of sight and out of mind' such developments are in the public mind. This paper presents a quantitative study of public opinions on a test site for wave energy currently under construction near the coast of the Southwest UK. The findings suggest general public support for wave energy as an economically beneficial method of power generation with few adverse side-effects. The merits of quantitative and qualitative research on public attitudes towards renewable-energy technologies are then discussed and concepts of risk and reward perception are used to explore the possible future dynamics of public attitudes towards 'future' renewables technologies like wave energy. We conclude with reflections on risk and reward perceptions as a heuristic device for defining future directions for research on public attitudes towards different renewable-energy technologies.

• Devine-Wright, P.  Public engagement with large-scale renewable energy technologies: breaking the cycle of NIMBYism.  WIREs Climate Change 2(1): 19-26, 2011.
  Open Access >>
  Read Abstract >>

  In response to the threat of climate change, many governments have set policy goals to rapidly and extensively increase the use of renewable energy in order to lessen reliance upon fossil fuels and reduce emissions of greenhouse gases. Such policy goals are ambitious, given past controversies over large-scale renewable energy projects, particularly onshore wind farms, that have occurred in many countries and involved bitter disputes between private developers and local 'NIMBYs' (not in my backyard) protestors. This article critically reviews recent research into how public engagement is conceived and practiced by policy makers and developers, with a specific focus upon the UK. The review reveals a distinction between different scales of technology deployment, with active public engagement only promoted at smaller scales, and a more passive role promoted at larger scales. This passive role stems from the influence of widely held NIMBY conceptions that presume the public to be an 'ever present danger' to development, arising from a deficit in factual knowledge and a surfeit of emotion, to be marginalized through streamlined planning processes and one-way engagement mechanisms. It is concluded that NIMBYism is a destructive, self-fulfilling way of thinking that risks undermining the fragile, qualified social consent that exists to increase renewable energy use. Breaking the cycle of NIMBYism requires new ways of thinking and practicing public engagement that better connect national policy making with local places directly affected by specific projects. Such a step would match the radical ambitions of rapid increases in renewable energy use with a process of change more likely to facilitate its achievement.

Policy and Legal Issues

• Todd, P.  Marine renewable energy and public rights.  Marine Policy 36(3): 667-672, 2011.  
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  Marine renewable energy is likely to be an important part of UK energy policy over the next decades. A start has already been made, but to generate power on a significant scale requires the use of vast areas of ocean, on which there are competing claims. Legislation, and in particular the Energy Act 2004, goes a long way towards giving developers the legal infrastructure they need, to invest with confidence. But it is far from perfect, in dealing with important competing rights. This article has a narrow (but important) focus. It assumes that there are no problems over jurisdiction or international law. It is concerned principally with the rights of UK citizens. The issue is about reconciling the generation of large-scale marine renewable energy with other legitimate uses of the sea, and in particular fishing and navigation rights.

• Jackson, A.L.R.  Renewable energy vs. biodiversity: Policy conflicts and the future of nature conservation.  Global Environmental Change 21(4): 1195-1208, 2011.
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  The European Union's (EU) network of nature conservation areas – Natura 2000 – covers almost 18% of EU territory, and is subject to strict legal protection, which is enforced by the European Commission, a supranational authority. Given the Natura 2000 network's size, conflicts between Natura 2000 and renewable energy projects are inevitable, particularly as countries push to meet their 2020 energy and emissions reduction targets by pursuing more – and larger – renewable energy projects. Focusing on two cases in the renewable energy sector – a hydroelectric dam in Portugal's Sabor valley, and a large tidal barrage in the UK's Severn estuary – this article shows that the EU's strict biodiversity protection regime could necessitate the rejection of many large renewable energy projects. That is, it may not be possible as a matter of EU law for national authorities to grant permission for such projects. The potential for such difficulties will be shown to be highly visible to policymakers, and could, this article argues, trigger negative impacts in terms of the rule of law, and negative feedbacks on nature conservation policies in the EU and, by way of precedent, globally. The legal issues presented here should not, this article argues, be regarded as insurmountable problems, nor as a trigger for reforms aimed at weakening biodiversity protections. Rather, these issues are better regarded as an opportunity for an open, informed, global debate regarding the relationship between biodiversity and climate change policies, and the hierarchy, if any, between them.

• Lacroix, D. and Pioch, S.  The multi-use in wind farm projects: more conflicts or a win-win opportunity?  Aquatic Living Resources 24(2): 129-135, 2011.   
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  The pressures on the use of the seashore are steadily rising, not only in developed countries but worldwide. Anthropogenic activity has long impacted the marine continental shelf down to a depth of approximately -200 m. New activities are now affecting this coastal space such as renewable energies, recreational uses and aquaculture in addition to the traditional ones of navigation or fishing. This evolution raises new sources of conflict amongst users which can require state involvement in order to manage the different stakeholders and pressure groups. However, the coastal space still offers a large potential for development for two reasons. Firstly, the physical three dimensional potential of this space enables the whole water column to be used, principally to increase the fishing productivity as in Japan. Secondly, innovative synergies can be created between socio-technical and ecological uses (a "fourth dimension") such as the eco-design of wind turbine foundations in order to create fish habitat or sea grass settlement. This new vision in "4D" for the design and the management of coastal infrastructure can potentially reduce the risk of conflict as different uses of the coastal space would not necessarily exclude one another. Indeed, several forms of synergy could be developed such as fisheries with aquaculture or biological sustainability with social acceptability. Until now, limited attempts at such an approach have been done. We suggest this is likely due to the absence of a common eco-engineering vision and the lack of experience amongst biologists and engineers in the co-construction of projects. This eco-engineering, or "green" vision, also takes into account the complexity and resilience of the ecosystem in the long term, if underwater engineered infrastructures are also "eco"-designed to increase ecological gain This new conception, for development within the coastal area, provides for an increased bio-oriented complexity to engineered structure and therefore a better resistance of the ecosystem in the long term to anthropogenic pressures and a reduction in multi-user conflicts.

Environmental Impacts

• Burger, J., Gordon, C., Lawrence, J., Newman, J., Forcey, G., and Vlietstra, L.  Risk evaluation for federally listed (roseate tern, piping plover) or candidate (red knot) bird species in offshore waters: A first step for managing the potential impacts of wind facility development on the Atlantic Outer Continental Shelf.  Renewable Energy 36(1): 338-351, 2011.  
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  With a worldwide increase in attention toward developing a reliance on renewable energy, there is a need to evaluate the effects of these facilities (solar, wind, hydropower) on ecosystems. We conduct a hazard and risk evaluation for three species of birds that are listed, or candidates for listing, as federally threatened or endangered in the US, and that might occur offshore on the Atlantic Outer Continental Shelf (AOCS) where wind power facilities could be developed. Our objectives were to: 1) provide conceptual models for exposure for each species, and 2) examine potential exposure and hazards of roseate tern (Sterna dougallii) and piping plover (Charadrius melodus, both federally endangered in the US) and red knot (Calidris canutus rufa, candidate species) in the AOCS. We used a weight-of-evidence approach to evaluate information from a review of technical literature. We developed conceptual models to examine the relative vulnerability of each species as a function of life stage and cycle (breeding, staging, migratory, wintering). These methods are useful for conducting environmental assessments when empirical data are insufficient for a full risk assessment. We determined that 1) Roseate terns are likely to be exposed to risk during the migratory and breeding season when they occur in the AOCS, as well as while staging. 2) Piping plovers are not likely to be at risk during the breeding season, but may be at risk during spring or fall migrations. Risk to this species is likely to be low from turbines located far from land as this species migrates mainly along the coast. 3) Red knots are potentially exposed to some risk during migration, especially long-distance migrants whose migratory routes take them over the AOCS. More information is required on exact spatio-temporal migration routes, flight altitudes (especially during ascent and descent), and behavioral avoidance of turbines by birds to ascertain their risk.

• Grecian, W.J., Inger, R., Attrill, M.J., Bearhop, S., Godley, B.J., Witt, M.J., and Votier, S.C.  Potential impacts of wave-powered marine renewable energy installations on marine birds.  Ibis 152(4): 683-697, 2010.
  Open Access >>
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  One potential approach to combat the impacts of climate change is the expansion of renewable energy installations, leading to an increase in the number of wave-powered marine renewable energy installations (MREIs). The consequences of increased use of these devices for birds are unknown. Here we describe the wave-powered energy-generating devices currently either operational or in development and review the potential threats and benefits of these to marine birds, their habitats and prey. Direct negative effects include risk of collision, disturbance, displacement and redirection during construction, operation and decommissioning. Above-water collision is a particular concern with wind-powered devices, but, because of their low profiles, the collision risk associated with wave-powered devices is likely to be much lower. Conversely, wave devices also pose the novel threat of underwater collision. Wave-energy-generating devices may indirectly impact marine birds by altering oceanographic processes and food availability, with implications for trophic cascades. Through appropriate mitigation, wave-powered MREIs offer the potential to enhance habitats. Direct positive effects may include provision of roosting sites, and indirect positive effects may include prey aggregation due to suitable substrates for sessile organisms or because they act as de facto protected areas. The cumulative effect of these could be the improvement and protection of foraging opportunities for marine birds. Recent studies have been critical of the methods used in the assessment of wind-powered MREI impacts, which lack sufficient sample sizes, controls or pre-development comparisons. Here we suggest solutions for the design of future studies into the effects of MREIs. Wave-powered MREIs are certain to become part of the marine environment, but with appropriate planning, mitigation and monitoring they have the potential to offer benefits to marine birds in the future.

• Brandt, M.J., Diederichs, A., Betke, K., and Nehls, G.  Responses of harbour porpoises to pile driving at the Horns Rev II offshore wind farm in the Danish North Sea.  Marine Ecology Progress Series 421: 205-216, 2011.   
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  Pile driving during offshore windfarm construction goes along with considerable noise emissions that potentially harm marine mammals in the vicinity and may cause large scale disturbances. Information on the scale of such disturbances is limited. Therefore, assessment and evaluation of the effects of offshore construction on marine mammals is difficult. During summer 2008, 91 monopile foundations were driven into the seabed during construction of the offshore wind farm Horns Rev II in the Danish North Sea. We investigated the spatial and temporal scale of behavioural responses of harbour porpoises Phocoena phocoena to construction noise using passive acoustic monitoring devices (T-PODs) deployed in a gradient sampling design. Porpoise acoustic activity was reduced by 100% during 1 h after pile driving and stayed below normal levels for 24 to 72 h at a distance of 2.6 km from the construction site. This period gradually decreased with increasing distance. A negative effect was detectable out to a mean distance of 17.8 km. At 22 km it was no longer apparent, instead, porpoise activity temporarily increased. Out to a distance of 4.7 km, the recovery time was longer than most pauses between pile driving events. Consequently, porpoise activity and possibly abundance were reduced over the entire 5 mo construction period. The behavioural response of harbour porpoises to pile driving lasted much longer than previously reported. This information should be considered when planning future wind farm construction.

• Lindeboom, H.J. et al.  Short-term ecological effects of an offshore wind farm in the Dutch coastal zone; a compilation.  Environmental Research Letters 6(3): art. 035101, 2011.
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  The number of offshore wind farms is increasing rapidly, leading to questions about the environmental impact of such farms. In the Netherlands, an extensive monitoring programme is being executed at the first offshore wind farm (Offshore Windfarm Egmond aan Zee, OWEZ). This letter compiles the short-term (two years) results on a large number of faunal groups obtained so far. Impacts were expected from the new hard substratum, the moving rotor blades, possible underwater noise and the exclusion of fisheries. The results indicate no short-term effects on the benthos in the sandy area between the generators, while the new hard substratum of the monopiles and the scouring protection led to the establishment of new species and new fauna communities. Bivalve recruitment was not impacted by the OWEZ wind farm. Species composition of recruits in OWEZ and the surrounding reference areas is correlated with mud content of the sediment and water depth irrespective the presence of OWEZ. Recruit abundances in OWEZ were correlated with mud content, most likely to be attributed not to the presence of the farm but to the absence of fisheries. The fish community was highly dynamic both in time and space. So far, only minor effects upon fish assemblages especially near the monopiles have been observed. Some fish species, such as cod, seem to find shelter inside the farm. More porpoise clicks were recorded inside the farm than in the reference areas outside the farm. Several bird species seem to avoid the park while others are indifferent or are even attracted. The effects of the wind farm on a highly variable ecosystem are described. Overall, the OWEZ wind farm acts as a new type of habitat with a higher biodiversity of benthic organisms, a possibly increased use of the area by the benthos, fish, marine mammals and some bird species and a decreased use by several other bird species.

• Perrow, M.R., Gilroy, J.J., Skeate, E.R., and Tomlinson, M.L.  Effects of the construction of Scroby Sands offshore wind farm on the prey base of Little tern Sternula albifrons at its most important UK colony.  Marine Pollution Bulletin 62(8): 1661-1670, 2011.
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  Despite widespread interest in the impacts of wind farms upon birds, few researchers have examined the potential for indirect or trophic (predator-prey) effects. Using surface trawls, we monitored prey abundance before and after construction of a 30 turbine offshore wind farm sited close to an internationally important colony of Little terns. Observations confirmed that young-of-the-year clupeids dominated chick diet, which trawl samples suggested were mainly herring. Multivariate modelling indicated a significant reduction in herring abundance from 2004 onwards that could not be explained by environmental factors. Intensely noisy monopile installation during the winter spawning period was suggested to be responsible. Reduced prey abundance corresponded with a significant decline in Little tern foraging success. Unprecedented egg abandonment and lack of chick hatching tentatively suggested a colony-scale response in some years. We urge a precautionary approach to the timing and duration of pile-driving activity supported with long-term targeted monitoring of sensitive receptors.

• Shields, M.A. et al.  Marine renewable energy: The ecological implications of altering the hydrodynamics of the marine environment.  Ocean and Coastal Management 54(1): 2-9, 2011.
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  Many countries now recognise the need for mitigation of climate change induced by human activities and have incorporated renewable energy resources within their energy policy. There are extensive resources of renewable energy within the marine environment and increasing interest in extracting energy from locations with either large tidal range, rapid flow with and without wave interaction, or large wave resources. However, the ecological implications of altering the hydrodynamics of the marine environment are poorly understood. Ecological data for areas targeted for marine renewable developments are often limited, not least because of the considerable challenges to sampling in high energy environments. In order to predict the scale and nature of ecological implications there is a need for greater understanding of the distribution and extent of the renewable energy resource and in turn, of how marine renewable energy installations (MREIs) may alter energy in the environment. Regional ecological implications of a MREI need to be considered against the greater and global ecological threat of climate change. Finally, it is recommended that the identification of species and biotopes susceptible to the removal of hydrokinetic energy could be a suitable strategy for understanding how a MREI may alter flow conditions.

• Langton, R., Davies, I.M., and Scott, B.E.  Seabird conservation and tidal stream and wave power generation: Information needs for predicting and managing potential impacts.  Marine Policy 35(5): 623-630, 2011.
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  Current development plans indicate that during the next decade there will be an increase in tidal stream and wave (TSW) power generation activity in Scottish Waters, together with the designation of additional offshore areas for seabird conservation. This paper summarises how TSW developments could affect seabirds, based on experience from other forms of disturbance, and explores the possible changes in behaviour and habitat that have the potential to increase a seabird's rate of energy acquisition (e.g. through enhancing prey abundance), or energy expenditure (e.g. through causing birds to commute further to find food, if they avoid foraging around developments placed in regular feeding areas). Changes to energy budgets could impact rates of reproduction and survival. Simulation modelling of seabird energetics and behaviour is one possible tool for predicting the direction and magnitude of population impacts caused by alterations to energy budgets, but is dependant on the availability and accuracy of necessary parameters. The later sections of the paper review the information needed for such models and shows that although some data are available regarding rates of energy expenditure during specific activities, more information is needed on seabird foraging rates. The paper also highlights how the susceptibility of a species to be impacted by future TSW development is likely to be related to their method of foraging, flight behaviour and ability to buffer against environmental fluctuations.

• Kadiri, M., Ahmadian, R., Bockelmann-Evans, B., Rauen, W., and Falconer, R.  A review of the potential water quality impacts of tidal renewable energy systems.  Renewable and Sustainable Energy Reviews 16(1): 329-341, 2012.
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  The continued increase in the demand for energy, growing recognition of climate change impacts, high oil and gas prices and the rapid depletion of fossil fuel reserves have led to an increased interest in the mass generation of electricity from renewable sources. Traditionally, this has been pursed through riverine hydropower plants, with onshore wind systems growing steadily in popularity and importance over the years. Other renewable energy resources, which were previously not economically attractive or technically feasible for large scale exploitation, are now being considered to form a significant part of the energy mix. Amongst these, marine and in particular, tidal energy resource has become a serious candidate for undergoing mass exploitation in the near future, particularly in places with a tidal range of 4 m or more. Tidal renewable energy systems are designed to extract the kinetic or potential energy flow and convert it into electricity. This can be achieved by placing tidal stream turbines in the path of high speed tidal currents or through tidal range schemes, where low head turbines are encapsulated in impoundment structures, much like in low head riverine hydropower schemes. It is thought that these systems, when implemented at scales required to generate substantial amounts of electricity, have the potential to significantly alter the tidal flow characteristics, which could have knock-on impacts on the hydro-environment. This review gathers together knowledge from different research areas to facilitate an evaluation of the potential hydro-environmental impacts of tidal renewable energy systems, with a particular focus on water quality. It highlights the relevance of hydro-environmental modelling in assessing potential impacts of proposed schemes and identifies areas where further research is needed. A case study is presented of recent modelling studies undertaken for the Severn Estuary.

• Leung, D.Y.C. and Yang, Y.  Wind energy development and its environmental impact: A review.  Renewable and Sustainable Energy Reviews 16(1): 1031-1039, 2012.
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  Wind energy, commonly recognized to be a clean and environmentally friendly renewable energy resource that can reduce our dependency on fossil fuels, has developed rapidly in recent years. Its mature technology and comparatively low cost make it promising as an important primary energy source in the future. However, there are potential environmental impacts due to the installation and operation of the wind turbines that cannot be ignored. This paper aims to provide an overview of world wind energy scenarios, the current status of wind turbine development, development trends of offshore wind farms, and the environmental and climatic impact of wind farms. The wake effect of wind turbines and modeling studies regarding this effect are also reviewed.

• Witt, M.J. et al.  Assessing wave energy effects on biodiversity: the Wave Hub experience.  Philosophical Transactions of the Royal Society of London [A] 370(1959): 502-529, 2012.
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  Marine renewable energy installations harnessing energy from wind, wave and tidal resources are likely to become a large part of the future energy mix worldwide. The potential to gather energy from waves has recently seen increasing interest, with pilot developments in several nations. Although technology to harness wave energy lags behind that of wind and tidal generation, it has the potential to contribute significantly to energy production. As wave energy technology matures and becomes more widespread, it is likely to result in further transformation of our coastal seas. Such changes are accompanied by uncertainty regarding their impacts on biodiversity. To date, impacts have not been assessed, as wave energy converters have yet to be fully developed. Therefore, there is a pressing need to build a framework of understanding regarding the potential impacts of these technologies, underpinned by methodologies that are transferable and scalable across sites to facilitate formal meta-analysis. We first review the potential positive and negative effects of wave energy generation, and then, with specific reference to our work at the Wave Hub (a wave energy test site in southwest England, UK), we set out the methodological approaches needed to assess possible effects of wave energy on biodiversity. We highlight the need for national and international research clusters to accelerate the implementation of wave energy, within a coherent understanding of potential effects -- both positive and negative.

• Margheritini, L., Hansen, A.M., and Frigaard, P.  A method for EIA scoping of wave energy converters -- based on classification of the used technology.  Environmental Impact Assessment Review 32(1): 33-44, 2011.
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  During the first decade of the 21st Century the World faces spread concern for global warming caused by rise of green house gasses produced mainly by combustion of fossil fuels. Under this latest spin all renewable energies run parallel in order to achieve sustainable development. Among them wave energy has an unequivocal potential and technology is ready to enter the market and contribute to the renewable energy sector. Yet, frameworks and regulations for wave energy development are not fully ready, experiencing a setback caused by lack of understanding of the interaction of the technologies and marine environment, lack of coordination from the competent Authorities regulating device deployment and conflicts of maritime areas utilization. The EIA within the consent process is central in the realization of full scale devices and often is the meeting point for technology, politics and public. This paper presents the development of a classification of wave energy converters that is based on the different impact the technologies are expected to have on the environment. This innovative classification can be used in order to simplify the scoping process for developers and authorities.

• Frid, C., Andonegi, E., Depestele, J., Judd, A., Rihan, D., Rogers, S.I., and Kenchington, E.  The environmental interactions of tidal and wave energy generation devices.  Environmental Impact Assessment Review 32(1): 133-139, 2011.
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  Global energy demand continues to grow and tidal and wave energy generation devices can provide a significant source of renewable energy. Technological developments in offshore engineering and the rising cost of traditional energy means that offshore energy resources will be economic in the next few years. While there is now a growing body of data on the ecological impacts of offshore wind farms, the scientific basis on which to make informed decisions about the environmental effects of other offshore energy developments is lacking. Tidal barrages have the potential to cause significant ecological impacts particularly on bird feeding areas when they are constructed at coastal estuaries or bays. Offshore tidal stream energy and wave energy collectors offer the scope for developments at varying scales. They also have the potential to alter habitats. A diversity of designs exist, including floating, mid-water column and seabed mounted devices, with a variety of moving-part configurations resulting in a unique complex of potential environmental effects for each device type, which are discussed to the extent possible.

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