TY - JOUR
T1 - A modelling approach for offshore wind farm feasibility with respect to ecosystem-based marine spatial planning
AU - Pınarbaşı, Kemal
AU - Galparsoro, Ibon
AU - Depellegrin, Daniel
AU - Bald, Juan
AU - Pérez-Morán, Germán
AU - Borja, Ángel
N1 - Publisher Copyright:
© 2019 Elsevier B.V.
PY - 2019/6/1
Y1 - 2019/6/1
N2 - Demand for renewable energy is increasing steadily and regulated by national and international policies. Offshore wind energy sector has been clearly the fastest in its development among other options, and development of new wind farms requires large ocean space. Therefore, there is a need of efficient spatial planning process, including the site selection constrained by technical (wind resource, coastal distance, seafloor) and environmental (impacts) factors and competence of uses. We present a novel approach, using Bayesian Belief Networks (BBN), for an integrated spatially explicit site feasibility identification for offshore wind farms. Our objectives are to: (i) develop a spatially explicit model that integrates the technical, economic, environmental and social dimensions; (ii) operationalize the BBN model; (iii) implement the model at local (Basque Country) and regional (North East Atlantic and Western Mediterranean), and (iv) develop and analyse future scenarios for wind farm installation in a local case study. Results demonstrated a total of 1% (23 km 2 ) of moderate feasibility areas in local scaled analysis, compared to 4% of (21,600 km 2 ) very high, and 5% (30,000 km 2 ) of high feasibility in larger scale analysis. The main challenges were data availability and discretization when trying to expand the model from local to regional level. The use of BBN models to determine the feasibility of offshore wind farm areas has been demonstrated adequate and possible, both at local and regional scales, allowing managers to take management decisions regarding marine spatial planning when including different activities, environmental problems and technological constraints.
AB - Demand for renewable energy is increasing steadily and regulated by national and international policies. Offshore wind energy sector has been clearly the fastest in its development among other options, and development of new wind farms requires large ocean space. Therefore, there is a need of efficient spatial planning process, including the site selection constrained by technical (wind resource, coastal distance, seafloor) and environmental (impacts) factors and competence of uses. We present a novel approach, using Bayesian Belief Networks (BBN), for an integrated spatially explicit site feasibility identification for offshore wind farms. Our objectives are to: (i) develop a spatially explicit model that integrates the technical, economic, environmental and social dimensions; (ii) operationalize the BBN model; (iii) implement the model at local (Basque Country) and regional (North East Atlantic and Western Mediterranean), and (iv) develop and analyse future scenarios for wind farm installation in a local case study. Results demonstrated a total of 1% (23 km 2 ) of moderate feasibility areas in local scaled analysis, compared to 4% of (21,600 km 2 ) very high, and 5% (30,000 km 2 ) of high feasibility in larger scale analysis. The main challenges were data availability and discretization when trying to expand the model from local to regional level. The use of BBN models to determine the feasibility of offshore wind farm areas has been demonstrated adequate and possible, both at local and regional scales, allowing managers to take management decisions regarding marine spatial planning when including different activities, environmental problems and technological constraints.
KW - Bayesian belief network
KW - Decision support tools
KW - Renewable energy
KW - Site identification
KW - Trade-off
UR - http://www.scopus.com/inward/record.url?scp=85062230033&partnerID=8YFLogxK
U2 - 10.1016/j.scitotenv.2019.02.268
DO - 10.1016/j.scitotenv.2019.02.268
M3 - Article
C2 - 30831368
AN - SCOPUS:85062230033
SN - 0048-9697
VL - 667
SP - 306
EP - 317
JO - Science of the Total Environment
JF - Science of the Total Environment
ER -