Abstract
Energy generated by land-based wind power is expected to play a crucial role in the decarbonisation of the economy. However, with the looming biodiversity and nature crises, spatial allocation of wind power can no longer be considered solely a trade-off against local disamenity costs. Emphasis should also be put on wider environmental impacts, especially if these challenge the sustainability of the renewable energy transition. We suggest a modelling system for selecting among a pool of potential wind power plants (WPPs) by combining an energy system model with a GIS analysis of WPP sites and surrounding viewscapes. The modelling approach integrates monetised local disamenity and carbon sequestration costs and places constraints on areas of importance for wilderness and biodiversity (W&B). Simulating scenarios for the Norwegian energy system towards 2050, we find that the southern part of Norway is the most favourable region for wind power siting when only the energy system surplus is considered. However, when local disamenity costs (and to a lesser extent carbon costs) and W&B constraints are added successively to the scenarios, it becomes increasingly beneficial to site WPPs in the northern part of Norway. We find that the W&B constraints have the largest impact on the spatial distribution of WPPs, while the monetised costs of satisfying these constraints are relatively small. Overall, our results show that there is a trade-off between local disamenities and loss of W&B. Siting wind power plants outside the visual proximity of households has a negative impact on W&B.
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1 Introduction
Energy generated by land-based wind power plants (WPPs) is expected to play a crucial role in the decarbonisation of the economy (IEA 2021). A challenging question facing regulators in many countries is how best to deploy WPPs geographically. The economic profitability of wind power differs spatially depending on wind conditions and necessary investments in turbines, infrastructure, and associated grids. Differences in expected prices across a country will also affect the optimal spatial allocation of WPPs in countries with several electricity price zones. At the same time, the deployment of land-based wind power raises several disamenity and environmental concerns, depending on the siting of the WPPs, such as noise, impaired landscape aesthetics, and loss of wilderness and biodiversity (W&B) (see e.g., reviews by Saidur et al. 2011; Mattmann et al. 2016; Zerrahn 2017). In addition, the construction of WPPs in natural areas affects carbon storage and sequestration through land-use changes, especially through the conversion of mires and forests.
From the regulator’s point of view, when a spatial deployment plan for the economic profitability of WPPs is being chosen, local disamenities and the wider environmental impacts of WPPs should matter. The total magnitude of the negative impacts of wind power production should be balanced against profitability and the climate contribution when choosing a specific siting for WPPs.
Research on spatial trade-offs in wind power deployment has to date focused primarily on the negative effects for nearby residents (Zerrahn 2017; Mattmann et al. 2016; Wen et al. 2018; Weinand et al. 2022), and only a few such studies have, to our knowledge, incorporated some measure of (primarily local) environmental and disamenity costs in energy system models (e.g., Lehmann et al. 2021a, b; Drechsler et al. 2017; Grimsrud et al. 2021; Salomon et al. 2020). However, with the latest assessment of the Intergovernmental Panel on Biodiversity and Ecosystem Services (IPBES 2019) and the Dasgupta review (Dasgupta 2021), it has become increasingly clear that the degradation and loss of nature and biodiversity may be just as serious as the climate crisis and that the two effects are mutually reinforcing. Hence, the impacts of land use on W&B must also be thoroughly assessed and considered in order to achieve optimal renewable energy deployment. This paper contributes to filling this gap in the literature by analysing spatial trade-offs between the economic, local welfare and wider environmental aspects of siting WPPs at national level in Norway. The paper also contributes to a wider and more heterogeneous literature on trade-offs in renewable energy deployment that investigates a range of different impacts (such as on land use and landscapes, scenics, biodiversity, equality, etc.) on different geographical levels by means of different methods (such as multicriteria analysis) (e.g.,Lehman et al. 2021b; Mckenna et al. 2021, 2022; Sasse and Trutnevyte 2020; Tafarte and Lehman 2021; Weinand et al. 2022).
The main contribution of the present paper is to provide a framework and an analysis of the evaluation and inclusion of various kinds of environmental impacts, more comprehensively assessed than previously, for the regulator’s decisions on the domestic siting of wind power production on land. We analyse the optimal siting of new potential wind power production capacity until 2050 based on concession applications obtained from the Norwegian Water Resources and Energy Directorate (NVE). As such, the potential analysed in this study is pre-selected by investors, while the true technical potential would be larger. From the total production capacity of 11 TWh, we apply a maximum target of 4 TWh from new land-based wind power in order to assess which WPPs are most favourable for investment. The selection of WPPs is subject to local nuisance and disamenity costs and the cost of carbon emissions due to land-use change, as well as constraints to prevent the loss of W&B. Hence, this type of analysis follows the approach by Bateman and Mace (2020), for example, arguing that a monetary value should not be placed on biodiversity impacts but rather constraints on the loss of critical natural capital for which there is limited substitutability.
By employing a fit-for-purpose, modified and updated energy system model for Norway (IFE-TIMES-Norway) (Loulou 2008; Loulou and Labriet 2008; Danebergs et al. 2021; Seljom et al. 2020), we explicitly derive the socially optimal selection of WPPs, taking into consideration both energy system revenues and costs, local disamenity costs, and the impacts of WPPs on W&B.
We also derive the energy system surplus of new wind power for different scenarios, with and without externality costs and the W&B constraints that have been included. The scenario analyses demonstrate spatial trade-offs and the explicit costs of accounting for W&B impacts. Although we conduct the analysis on Norwegian data, the analytical framework for optimal spatial selection of WPPs can be applied across all countries.
In the next section, we describe the analytical framework, while section three explains the empirical methods used, including (1) the energy system model, IFE-TIMES-Norway, (2) how local disamenity impacts and carbon emissions are estimated and monetised, and (3) the derivation of W&B constraints. In section four, we first present the most important and illustrative scenarios for the spatial distribution of WPPs where we successively introduce more comprehensive environmental costs and constraints. Second, we present the most important numerical results from model simulations and a sensitivity analysis. Concluding remarks are given in section five.
2 Analytical Framework
While an elaborated dynamic numerical model is described in Sect. 3.1, Sect. 2 introduces a simplified analytical framework explaining the basic concept of the optimisation problems considered in the paper. We first employ the analytical model to present the characteristics of a cost-effective deployment of WPPs from an energy system perspective. We then modify this model to include the monetised environmental costs. Finally, we add constraints, as proposed by Bateman and Mace (2020), on the construction of new WPPs on land areas important for wilderness and biodiversity (W&B). We chose this approach as it is often considered both controversial and methodologically challenging to place a value on impacts on biodiversity and to determine the “extent of the market” of affected households where substantial non-use values are likely to be present. Hence, such impacts are sometimes included as constraints instead (e.g., Bateman et al. 2013). The implementation of these constraints is further described in Sect. 3.2.3.
Let \(i=\{\mathrm{1,2},\dots ,J\}\) denote all new potential WPPs, where WPPi is characterised by its average annual electricity production (\(q_{i}\)), its production and investment costs and its location.Footnote 1, Footnote 2, Footnote 3 We assume a target, Q, for new wind energy production, where \(Q \le \sum\nolimits_{i \in J} {q_{i} }\). We compare three different optimisation problems, each increasing the wind energy production by Q. First, we derive the selection of WPPs which maximise the energy system surplus, but without taking account of environmental costs (see Sect. 2.1). Second, we derive the selection of WPPs which maximise the energy system surplus, while also including monetised environmental costs (see Sect. 2.2). In the third optimisation problem, we exclude from the set of new potential WPPs those power plants that overlap (by more than a certain percentage) with valuable areas in terms of wilderness and biodiversity richness, i.e., we add W&B constraints. From the remaining WPPs, we select those which maximise the energy system surplus after monetised environmental costs have been taken into account (see Sect. 2.3).
The new wind energy production will affect the costs and revenues of the entire energy system in multiple ways and will depend on which of the WPPs is developed. The WPPs typically differ in investment costs in terms of scale, turbine characteristics, and grid connection. The production revenues of WPPs also depend on the siting/location since we are considering an entire energy system where there are several different price zones. Furthermore, investments in new WPPs also affect the electricity price and new grid investments, which in turn affect the profits of incumbent energy producers. We define the energy system surplus (ESS) as the system income in excess of from the cost of producing Q units of new wind power. As discussed above, ESS will depend on the choice of WPPs to be developed. Let \(\Omega_{1} ,\Omega_{2} ,.....,\Omega_{K}\) denote the subsets of J for which the production target is satisfied. We can then write ESS as a function, F, of the chosen subset of WPPs. If \(\Omega_{k}\) is the chosen subset, then \(ESS(\Omega_{k} ) = F\left( {\sum\limits_{{i \in \Omega_{k} }} {q_{i} } } \right)\).
The WPP selection will also affect the total environmental costs, as the impact on the environment differs across WPPs. For each WPPi, we assign a monetised environmental cost associated with the location of the WPP. The environmental cost is denoted by \(e_{i}\) = TDi + TCi, where TDi is the total disamenity cost for affected households when the WPP is in operation, and TCi is the total carbon cost caused by land-use change from constructing the new WPP. Furthermore, let \({\delta }_{i}\) denote the percentage overlap between the land area required for WPPi and land areas that are considered valuable in terms of wilderness and biodiversity richness. The W&B constraint requires that \({\delta }_{i}\le d\), where d is a set restriction on the maximum irreversible loss of such land areas, as required by societal goals. Let \({\lambda }_{land}\) be the shadow price of the constraint, where \({\lambda }_{land}>0\) implies that the constraint is binding.
We consider different scenarios for an optimal choice of WPP development, given a target of new wind energy production (Q), with and without including the monetised environmental costs and the additional requirements to prevent impacts on wilderness and biodiversity-rich areas.
2.1 Cost-Effective Solution: Maximising Energy System Surplus Excluding Environmental Costs
Let \(\Omega_{B}\) denote the subset of WPPs that maximise the energy system surplus of Q. We refer to this outcome as the cost-effective spatial distribution of WPPs, i.e., environmental costs are not included in the optimisation. The net energy system revenue (ESSB), total monetised environmental costs (EB), total production, and monetised welfare (MWB) for this distribution are expressed as follows:
2.2 Maximising the Energy System Surplus Including Monetised Environmental Costs But Excluding Wilderness and Biodiversity Constraints
Let \(\Omega_{N}\) denote the subset of WPPs which maximise the energy system surplus of Q including monetised environmental costs. The net energy system revenue (ESSN), total monetised environmental costs (EN), total production, and monetised welfare (MWN) of this distribution are expressed as follows:
2.3 Socially Optimal Solution: Maximising the Energy System Surplus Including Monetised Environmental Costs and Wilderness and Biodiversity Constraints
Let \(\Omega_{S}\) be the subset of WPPs that maximises the energy system surplus of Q including monetised environmental costs and that satisfies the W&B constraints. Under the condition of a binding W&B constraint, the net energy system revenue (ESSS), total monetised environmental costs (ES), total production, and monetised welfare (MWS) of this distribution are expressed as:
2.4 Anticipated Results of the Numerical Analysis
As the environmental costs are not included in the cost-effective solution, the WPPs included in \(\Omega_{B}\) are expected to differ substantially from the WPPs included in \(\Omega_{N}\), which in turn differ from the WPPs included in \(\Omega_{S}\). As the model gradually incorporates new costs and the analysis becomes more constrained, it is expected that \(ESS^{B} > ESS^{N} > ESS^{S} .\)
Furthermore, since the model in Sect. 2.2 includes the environmental costs in the optimisation problem, as opposed to the cost-effective solution, it is expected that:
Both the model in Sect. 2.2 and in Sect. 2.3 include the monetised environmental costs, but the latter also has the W&B constraints. As the positive welfare impact of avoiding WPP development of valuable nature is not included in our measurement of monetised welfare, we expect that \(MW^{N} > MW^{S}\). We can interpret \(MW^{N} - MW^{S}\) as the monetised welfare cost of the W&B constraints.
In the cost-effective solution, the energy system costs will be the determining factor for the selection of WPPs. The monetised environmental costs include inter alia the quantifiable welfare loss of neighbouring households. Hence, the solution that only includes environmental costs that are monetised will typically lead to less development of WPPs located near residential areas and thus shift WPP development into land areas that are valuable in terms of their W&B (nature areas). Adding the W&B constraints, on the other hand, will shift WPPs out of nature areas and nearer the more populated areas. Hence, we expect there to be a trade-off between reducing the neighbouring households’ discomfort and preserving valuable natural areas for the benefit of the wider society. Our modelling approach permits us to estimate this trade-off by assessing \(MW^{S} - MW^{B}\) and \(E^{S} - E^{B}\).
In the numerical modelling we refer to the solution of the optimisation problem given by Eq. (3) as the socially optimal selection of WPPs, although, as noted in the introduction, the new potential WPPs (i = {1, 2,…, J}) analysed in this study only cover WPPs that have applied for production concessions. The true technical potential would be larger, as licence applications are based on investors’ assessment of profitable locations. Similarly, there may be additional potential that entails a lower environmental impact. Furthermore, there may be costs and benefits of WPPs other than energy system costs and environmental impacts that will not be taken into account in our numerical modelling. Hence, socially optimal selection must be interpreted as the selection of WPPs from among the pre-selected locations that will maximise the energy system surplus by producing Q units of new wind power when the monetised environmental costs are included, and the W&B constraints are satisfied. As all WPPs have a defined geographical location, all potential selections of WPPs lead to a well-defined spatial distribution of WPPs across the country. We therefore use the phrase “selection of WPPs” and “spatial distribution” of WPPs interchangeably in the paper.
3 Empirical Methods
Given the analytical model above, we explain first the empirical modelling framework (the IFE-TIMES-Norway model), and second, how the monetised impacts and W&B constraints are calculated and integrated into the model.
3.1 Energy system Model (IFE-TIMES-Norway)
3.1.1 About the Model: General Characteristics
IFE-TIMES-Norway (Loulou 2008; Loulou and Labriet 2008; Danebergs et al. 2021) is a long-term optimisation model of the Norwegian energy system that is generated by TIMES (The Integrated MARKAL-EFOM System) modelling framework. It is a bottom-up framework that provides a detailed techno-economic description of resources, energy carriers, conversion technologies, and energy demand. TIMES models minimise the total discounted cost of a given energy system for meeting the demand for energy services for the specified regions over the period analysed. The total energy system cost includes investment costs in both supply and demand technologies, operation and maintenance costs, and income from electricity exports to and the costs of electricity imports from countries outside Norway.
The model has a detailed description of the end-use of energy, with demand for energy services divided into numerous end-use categories within industry, construction, and transport. The demand may be met by both existing and new technologies, using energy carriers such as electricity, bioenergy, district heating, hydrogen and fossil fuels. Other input data include fuel prices, electricity prices in countries with transmission capacity to Norway, renewable resources, and the characteristics of the technology such as costs, efficiencies, lifetime, and learning curves.
Spatially, the model covers five geographical regions in Norway, corresponding to the current electricity spot market price zones. Figure 1 provides an illustration of the price zones with their respective existing wind power capacities and potentials. The model provides operational and investment decisions from the initial year, 2018, up to 2050. To capture operational variations in energy generation and end-use, each year is divided into 96 time slices where each of the four seasons (spring, summer, fall, winter) is represented by a 24-h day.
3.1.2 Assumptions and Methods for Incorporating WPPs in TIMES
To investigate the most efficient geographical selection of new WPPs, the IFE-TIMES-Norway model has been modified to include a more detailed representation of existing and potentially new land-based wind power parks in Norway. Information about each WPP is obtained from NVE (2022). In the data gathering process, wind parks have been categorised according to their status: “in operation”, “concession granted” and “under assessment”. The latter category includes WPPs for which there is a concession application or for which plans have been announced. Applications that have been rejected, therefore, do not form part of potential investment in new wind power. The same applies to applications that have been put on hold, as most of these are quite old and will require new applications that would also have to be granted. Lastly, applications that were submitted before 2010 and for which no updates have been reported, have been excluded. In total, 4.6 GW capacity is already in operation with the first WPP installed in 1998. As regards the potential for new wind power capacity, 26 WPPs have been included in the analysis, with concessions granted for 1.2 GW and 1.9 GW still under assessment. This corresponds to approximately 15.5 TWh of existing wind power production and 11 TWh from potential new WPPs. WPPs that are already in operation are included in the model as existing capacity (15.5 TWh). However, we allow for the possibility of reinvestment in these plants (i.e., renewals of any expiring production concessions at current sites). Reinvestment in existing capacity is allowed at a 20% lower cost than the initial investment due to reduced costs for new infrastructure and wind turbines.Footnote 4 The possible capacity of reinvested WPPs is restricted by regulations on existing WPP capacity.
Based on the concession applications included in this analysis, only WPPs in areas NO2, NO3 and NO4 have been assessed. In other words, no new wind capacity is assumed to be built in NO1 and NO5. The former regions will henceforth be referred to as South (NO2), Central (NO3), and North (NO4).
An overview of the existing and new WPPs included in this analysis, along with specifications, can be found in “Appendix A”, Tables 4 and 5. Model input data include investment costs, operation and maintenance (O&M) costs, existing/applied capacity, and the associated capacity factor for each WPP. Investment costs are based on data from NVE and the respective municipality/developer, while O&M costs are assumed to be equal for all plants at 10 €/MWh (IRENA 2020; NVE 2019).Footnote 5 The year of investment for new WPPs is fixed as 2025, with a technology learning pace of 16% from the starting year of 2018 to 2025 (IRENA 2019). Moreover, as investment costs tend to be estimated at the time of the submission of the concession application, and these often go back many years, an annual cost reduction of 3% from the cost year to 2018 is applied to wind turbines that are not yet in operation. These technology learning rates are based on projections from IRENA (2019). Lastly, all cost inputs to the model are in 2020 prices. The WPPs have a lifetime of 25 years, and reinvested plants can operate for an additional 25 years. The assumption that all wind parks are installed in the same year is made to simplify the environmental cost calculation as the carbon price differs depending on the year of installation.
Since the purpose of this analysis is to assess the optimal spatial selection of new wind power, we assume that only a portion of the total potential of 11 TWh for which concessions have been applied will be implemented. Considering the strong opposition to land-based wind power development in Norway and the 3-year-long hold in the concession process, a target of 4 TWh annual production from new land-based wind power is assumed. This is added as a restriction in the IFE-TIMES-Norway model, in which annual wind power production from new WPPs is constrained to 4 TWh in all years following 2025. Note that production from existing WPPs and reinvested WPPs are not included in this constraint, meaning that wind power production by 2050 could potentially reach 19.5 TWh (i.e., 15.5 + 4 TWh) if there is reinvestment in all existing plants. This is considered a reasonable assumption as reinvested WPPs will not require new land-use change and are likely to face less opposition than new installations.
In IFE-TIMES-Norway, the electricity price in Norway is a result of the model, but its magnitude and development depend largely on the assumptions of different parameters. In particular, the electricity price in Norway follows, to a large degree, market prices in Europe. Given higher CO2 prices and stronger penetration of variable renewable energy, prices are expected to increase and become more volatile (Statnett 2020). The impact is uncertain, however, and will depend on several factors such as gas prices, the CO2 price, industry development, and renewable expansion. The development in electricity prices in Norway, also on a regional level, will further impact the optimal spatial distribution of WPPs. The analysis is therefore uses two different price sets for neighbouring countries with transmission cables to Norway.Footnote 6 A baseline scenario is used for the initial analysis, while a sensitivity analysis is performed with a high electricity price scenario. The electricity price profiles for European countries are consistent with the carbon price pathways used for the carbon emission cost calculaton (3.2.2) and presented in Table 6, “Appendix B”. Average electricity price developments for the two scenarios for some selected countries are presented in Fig. 8, Appendix B.
3.2 Monetised Local Disamenity and Carbon Costs and the Wilderness and Biodiversity Constraints
A WPP affects the environment in several ways. We distinguish between disamenity impacts affecting households in the vicinity of WPPs and more general environmental impacts affecting society as a whole (wider environmental costs). The latter category includes (1) monetised values of carbon emissions from land-use change due to the establishment of the WPPs, and (2) impacts on land areas important for wildlife and biodiversity included as constraints in the model. In addition to the cost of direct emissions from WPPs, the model also captures the indirect emission reductions from substituting brown with green electricity consumption in Norway (e.g., EVs instead of fossil fuel cars). The benefit of indirect emission reductions will, however, not be affected by the spatial selection of the individual WPPs, only the total production volume. On this subject, there will be no differences between the scenarios as the same production target is defined for all.
3.2.1 Local Disamenity Costs
Neighbouring households face noise pollution, light flickering, ice fall incidents, deterioration of local nature and recreational areas, and reduced visual aesthetics of the local landscape (Zerrahn 2017). We estimated a total local disamenity cost for each WPP in an attempt to capture this “bundle” of impacts.Footnote 7 The total local disamenity costs, TDi, is a function of the disamenity costs for the sum of the households, hi, affected in the vicinity of WPPi:
where Cd is the disamenity cost. We assume that the affected households are all located at a distance of less than 4 km from the WPPi as well as households within 4 to 30 km of WPPi if it is in the viewscape of the household.
To capture the disamenity costs of households in the vicinity of existing and potential new WPPs, GIS analysis combined with land registry data was used to identify the number of households in each affected residential building. Vacation homes may also be in the vicinity of WPPs. A vacation home is typically occupied by one household for a certain percentage of the year. GIS analysis was used to identify residential buildings and vacation homes with a WPP, existing or potential new, in their viewscape. For existing WPPs, the viewscape analysis relied on information from NVE on the height of turbines and the siting in the landscape of each WPP. For potential new WPPs, the viewscape analysis is more challenging, as information on the number of turbines, their height and their placement is not available. Information on the total capacity (MW) applied for in the concession application for each new potential WPP is however provided by NVE. We therefore used data for WPPs that came into operation in 2021 to estimate the number of turbines for each potential WPP development. For the WPPs that came into operation in 2021, the average capacity of each turbine is 5 MWFootnote 8and the average turbine height is 171 m. For the viewscape analysis for new potential WPPs, we assumed that the estimated number of turbines would have a height of 171 m and that these would be distributed evenly across the area indicated in the concession application for the WPP.
While households in residential buildings are assumed to be affected all year round, households in vacation homes are assumed to be affected in proportion to the share of the year they use their vacation home. For this, we used a mean estimate of 15%, based on survey data from the last five years on the number of days Norwegians use their vacation homes (Prognosis Centre 2021).Footnote 9
To get an estimate of the total local disamenity cost for each WPP, we apply a constant cost per household per turbine per year, independent of the number of turbines at the site and the distance from the site. It is included in the model as €/MW/year. In our base case, we use an average, annual mean willingness to pay (WTP) to avoid one turbine of €23 per household taken from the only two local non-market valuation studies we are aware of from Norway. Both are choice experiment studies: one from a proposed WPP in the municipality of Sandnes on the west coast (García et al. 2016, WTP estimate used in Grimsrud et al. 2021) and one from a proposed WPP in the municipality of Aurskog-Høland in eastern Norway (Dugstad et al. 2022). Because of well-known concerns related to hypothetical bias in choice experiment and other stated preference methods, we choose conservative estimates from these studies. Since they do not specifically analyse or demonstrate distance decay in their data, and their estimates are based on mean WTP from the sampled municipality population, we assume in our base case a constant per turbine cost applying to all households and vacation homeowners in the viewscape of each WPP.
There is uncertainty regarding the local disamenity cost specification. Both theoretical and empirical studies generally show ambiguous results for distance decay effects, which determine boundaries for affected populations (e.g., Glenk et al. 2020) and the scope effects (e.g., Dugstad et al. 2021) of environmental impacts. This is also the case for wind power externalities, e.g., Wen et al. (2018) and Mattmann et al. (2016). Some studies apply a distance decay function (e.g., Lehmann et al. 2021a, b and Ruhnau et al. 2022) and/or use a close boundary around each WPP (e.g., Krekel and Zerrahn 2017).Footnote 10 We therefore use three alternative specifications for sensitivity. First, we base our distance decay function on Lehmann et al. (2021a; b), Footnote 11
and translate their distance decay function, which calculates per month disamenity costs measured in € from German studies as a function of a household’s distance dh (m) from a wind turbine, into an annual disamenity cost depending on distance to a WPP. We assume, as do Lehmann et al. (2021a; b), that the per turbine cost is linear in the number of turbines (located as part of the same WPP or adjacent ones). The disamenity cost used in the sensitivity analysis that assumes distance decay is higher than the cost in our base case if the distance of the household to the WPP is less than 3822 m, but lower than the base case cost for distances beyond 3833 m. For households at a distance greater than 4000 m, no environmental cost is included in this sensitivity analysis. For sensitivity, we also use low and high alternatives, where we set the boundary at 4 km and double the cost for the full viewscape. As in the main analysis, we assume that each household incurs this full cost and that only 15% of this cost is incurred if the building is a vacation home.
3.2.2 Carbon Emission Cost of Land-Use Change
When building a WPP, only a small share of the land set aside for the power plant will be converted from undeveloped to developed land. According to NVE (2019, p. 18), around 4% of the area of a WPP concession is directly affected by infrastructure. Some of this may be restored after the roads have been built, and management practices would affect land-use changes and subsequent CO2 emissions. We do not have access to information about carbon emissions due to the felling of trees and drainage of mires, but by using GIS analysis we have access to the amount of biomass stored in the forests, below and above ground, the forested area, and the area of mires for each concession area (Nowell et al. 2020). For all WPPs, we assume that a share of 4% of all types of land in the concession area is converted into developed land. Furthermore, we assume that the loss of biomass due to the felling of trees will not be replaced and that the excavation of mires to achieve a firm foundation for infrastructure leads to direct (and immediate) emissions of CO2. The emissions from the removal of mires correspond to the carbon content of the mires. Excavating mires and converting forests into developed land also implies that a source of carbon sequestration is removed, see inter alia Nayak et al. (2010) and de Wit et al. (2015). This impact is assumed to last “forever”.
The total carbon costs for WPPi (\(TC_{i}\)) thus consist of four elements:
where \(CE_{iF}^{{}}\) represents emissions costs from loss of stored carbon in forests (measured in tons of biomass above and below ground), during the construction year, \(CE_{iM}^{{}}\) is the carbon cost of emissions from loss of mires, also in the construction year, and CSiM and \(CS_{iF}^{{}}\) are the carbon costs of loss of future CO2 uptake in mires and forests, respectively. For the monetary social cost of the emissions from land-use changes, we use the scenarios for EU-ETS prices presented in “Appendix B”. The base case prices are used for the initial analysis, while a sensitivity analysis is performed for the high carbon price pathway.
As we do not have information on the depth of the mires on each site, we rely on average numbers for Norway and set the depth at 1.5 m (de Wit et al. 2015, reports 1.7 m, whereas Gorham 1991, reports 1.1 m). For the average carbon content per metre depth, we use the same average factor as in the official report to the UNFCCC, which is set as 0.1683 tons of CO2 (Norwegian Environment Agency, 2022). In calculating the carbon costs of lost sequestration in forests and mires, we use the estimates of carbon accumulation in peatland soils, trees and forest soil provided by de Wit et al. 2015. “Appendix C” provides a detailed description of the calculations of carbon costs.
By employing the carbon price path (base), presented in “Appendix B” we find that:
where \(M_{i}\) and \(F_{i}\) are the area (m2) of mires and forests, respectively, in the concession area of WPPi, and \(BMA_{i}\) and \(BMB_{i}\) are tons of biomass stored per m2 of forest, above and below ground, respectively. As the average outcome of \((BMA_{i} + BMB_{i} )\) is around 0.007, we see that loss of mires has a significantly larger impact on carbon costs than a loss of forest area per m2. Furthermore, the loss of future carbon sequestration due to the loss of forest area and mires (\(CS_{iF}\) and \(CS_{iM}\)) is of significantly less importance for the carbon costs than the immediate emissions during the construction phase (\(CE_{iF}\) and \(CE_{iM}\)).Footnote 12 For existing WPPs where there is reinvestment, the carbon emissions from land-use change are assumed to be sunk costs and are therefore set at zero.
3.2.3 Loss of Land of Importance for Wilderness and Biodiversity
Wind farms can negatively affect wildlife and habitats either through direct impacts, such as bird collisions with wind turbine rotors or loss of habitat to infrastructure construction, or indirectly, for example by acting as migration barriers (Arnett and May 2016; Kuvlesky et al. 2007). We use Nowell et al. (2020) as a starting point to take account of the impacts on biodiversity and wilderness as a result of land-use change for each WPP construction. Two criteria were assessed, namely the potential loss of wilderness areas and the potential loss of biodiversity. Wilderness is defined as areas free from infrastructure where flora and fauna can exist undisturbed. A loss of wilderness can result in fragmentation, increased potential for environmental barriers and/or habitat loss (Di Marco et al. 2019). Since the exact area or location of construction was not available for all WPPs, we assessed the potential impact according to how much of each WPP was classified as wilderness. Instead of using the simple INONFootnote 13 indicator to identify wilderness areas as Nowell et al. (2020) did, we used the so-called Infrastructure Index (Bakkestuen et al. 2022). The INON indicator has been criticised for being too simplistic (e.g., not distinguishing between the intensity and extent of infrastructure impact in an area). The Infrastructure Index measures the frequency of infrastructure within a 500 m circle around each pixel. It takes a value of 0 (min) if the area is completely devoid of human infrastructure and 13.23 (max) if the area is completely covered in human construction (e.g., a dense urban area) (Jakobsson et al. 2020).Footnote 14 The advantage of using this indicator rather than the INON maps is that the intensity of infrastructure can be taken into account, and undisturbed areas are mapped at a finer spatial resolution. In this study, an area-weighted sum of the infrastructure index was calculated for each area of the WPP. This approach gave more insight into the distribution of different intensities of infrastructure in each wind farm area while controlling for the size of the wind farm. All WPPs with a score below 1.8 were considered to be wilderness areas according to Erikstad et al. (2013) and any construction would therefore impact wilderness areas.
To assess the second criterion for impact on biodiversity several spatial indicators were used, based on guidance from the Norwegian Environment Agency (NEA), namely: (1) overlap with functional areas (NEA 2019), (2) nationally and locally nature types of importance for biodiversity (NEA 2001), (3) protected areas NEA 2022), and (4) the ranges of wild reindeer, a species that Norway has a special responsibility for managing (NEA 2018). Furthermore, each WPP was also evaluated to see if it overlapped with threatened species hotspots for insects and arachnids, bryophytes, fungi, lichens, and vascular plants (Olsen et al. 2018, 2020). Wind farms have been found to have the greatest impact on birds and bats, but also influence how other types of wildlife use areas near wind turbines and other associated infrastructure (Arnett and May 2016; Kuvlesky et al. 2007). While comprehensive national datasets are not yet available for migration routes, mapped functional areas were used as an indicator of the impact on breeding, nesting and grazing areas for priority, red-listed species and other species of wildlife.
Important nature types were included as an indicator of the impact on ecosystems. Overlap with protected areas was used as an additional indicator of important habitats and the species associated with them. Wild reindeer breeding, calving, migration, and grazing areas were also included as an indicator. Wild reindeer have been shown to avoid WPPs and the construction of wind farms alters migration routes and corridors, which are already severely restricted in Norway because of infrastructure (Skarin et al. 2015, 2018). Finally, hotspots for insects and arachnids, bryophytes, fungi, lichen, and vascular plants were used as an indicator of threatened species. These hotspots are based on the top 10% probability of finding threatened species at a given location.
Spatial overlap with one or more of these indicators meant that a WPP would have a potential impact on biodiversity. Nowell et al. (2020) classified WPPs according to whether the concession area overlapped indicators by more than 5%.Footnote 15 Since Nowell et al. (2020) used a 1 km buffer around WPP boundaries that was not used in the present analysis, the overlap threshold was reevaluated and set to 1% in this study. A sensitivity analysis revealed that a loss of 1% of the area could in some cases exceed 1 km2 of important habitat, which implies a significant impact on biodiversity. Of the cases with less than 1% overlap, the greatest loss of important habitats was 0.05 km2, which is a considerable reduction. An increase to 2% resulted in almost a tripling of the area impacted (i.e., 2.7 km2). Therefore, 1% was chosen as the threshold, meaning that if the overlap with one or more indicators was greater than 1% of the WPP area, then the WPP was flagged as having a potential impact on biodiversity.
We do not attach a specific monetary value to the loss of wilderness and loss of land that is important for biodiversity and wildlife, but instead investigate the social cost of providing a certain amount of wind power if all WPPs that do not meet the criteria are excluded from the potential set of WPPs. Hence, these concerns are implemented in the model analysis as on–off constraints, i.e., constraints that are activated whenever a wind farm violates the abovementioned indicators.
For sensitivity, we added a third, highly relevant, but principally different, type of constraint from a recent Supreme Court verdict on the indigenous right of the Sami people to conduct their traditional reindeer husbandry unaffected by land-based wind power. Herding reindeer is an important cultural and economic activity for the Sami people, particularly in Northern Norway but also in many other parts of the country.Footnote 16 In late 2021, the court sided with reindeer owners against a wind power company in a case regarding the largest WPP in Norway (and Europe) in Fosen in central Norway. It was concluded that the WPP violates their indigenous rights. The consequence of this verdict for Fosen and other existing or new WPPs is not yet clear. It could be that future WPPs must remain completely outside reindeer herding areas. We performed a spatial analysis to determine the area of overlap between areas used for reindeer husbandry and WPPs. This criterion consisted of 7 indicators representing the four seasonal grazing areas,Footnote 17 movement corridors,Footnote 18 staging areas,Footnote 19 and administrative areas.Footnote 20 As with the other indicators, if there was more than a 1% overlap for one or more of the reindeer indicators, the WPP was flagged as having an impact on reindeer husbandry.Footnote 21
National scale, freely available spatial datasets were used in the spatial analysis such that each WPP could be assessed according to the same criteria. These datasets may have some geometric error due to the mapping scale. The spatial analysis was performed in ArcMap 10.8 using the Spatial Analyst extension (ESRI). Table 8 in “Appendix D” shows which criterion is activated for each WPP.
4 Results of Model Simulations
4.1 Land-Based Wind Power Deployment Scenarios
Five different land-based wind power development scenarios were analysed, see Table 1.
In all the scenarios, the annual production from new WPPs is restricted to 4 TWh, as explained in Sect. 3.1.2. Reinvestment in existing capacity is not included in this target and are limited by the initial capacity of the plant. Moreover, reinvestment in already established WPPs is assumed to not cause further land use change. Therefore, such reinvestment is assumed to be emission-free as related to land use change. Emission costs from land-use change and the loss of wildlife and undisturbed land areas from reinvestment are therefore considered sunk costs, and not included in the analysis. However, local disamenity costs for reinvested WPPs are included, with the assumption that the new wind turbine height remains the same as for the initial turbines.
In scenarios S2-S4, we consider the impact of only one or two types of environmental externalities at a time, whereas scenario S5 includes all the environmental externalities simultaneously (except the impact on reindeer husbandry). This scenario can be considered to yield the socially optimal siting of new wind power capacity if the goal of limiting impacts on undisturbed land, wildlife and biodiversity is to be fulfilled. We start in the next section by presenting results for the spatial distribution of WPPs followed by the derived energy system surplus, environmental costs and welfare impacts. We conclude with some sensitivity considerations, including the results of imposing a third constraint: the impact on reindeer husbandry.
4.2 Spatial Distribution of WPPs Across Scenarios
Figure 2 illustrates the spatial distribution of new wind power capacity in Norway resulting from the TIMES model simulations for the five main wind power deployment scenarios. The base scenario represents the optimal, cost-effective distribution when no environmental impacts are considered. From an energy system perspective, the South is the most favourable region for wind power investment, with a maximum potential of 542 MW. The optimal distribution of the WPPs is determined by differences in both investment costs and wind conditions, but also, to a large extent, by differences in electricity prices in the different regions. While the South has the highest electricity price in the model results, the North is consistently the region with the lowest electricity price across all scenarios making it the least appropriate region for wind power investment. Moreover, the South is more closely connected to the European energy system, which makes the export of wind power energy possible without the need for large domestic grid investments. A total of 16 WPPs, of 26 possible, are chosen in the cost-effective scenario.
The second scenario, CC (S2), includes the emission cost of land-use change resulting from mire excavations and loss of biomass. As illustrated by Fig. 2, incorporating these costs has only a minor impact on the number of new WPP even though excavation of mires has a large impact on CO2 emissions (per m2). In fact, the same 16 WPPs are chosen, but there is a slightly higher capacity investment for the single WPP in the North accompanied with a slightly reduced investment of WPP’s in the Central region. The reason for the impact being small is that few WPPs have large areas of mires within the concession area and, more importantly, only a small part (4%) of the concession area is assumed to be affected by the establishment of a WPP. Internalising the welfare loss for neighbouring households and vacation homeowners (S3) leads to a 10% lower investment share in the South. This is due to the higher population compared to the northern parts of Norway. Similarly, new power plants in the North will generally have lower local disamenity costs than those located further south.
The same tendency can be observed when the impact on W&B is incorporated in the analysis (S4 and S5). In general, the more of the monetised environmental costs and W&B constraints that are incorporated, the more beneficial WPPs become in the northern part of Norway. For the wilderness constraint (WILD), whereby WPPs in areas with low human infrastructure impact are excluded, results show that this constraint alone leads to a 5% shift in investment share from the South to the Central region. In total, 5 of the 7 WPPs violating this constraint are initially part of the optimal investment solution from S1, indicating that most of the WPPs in violation of the wilderness constraint are considered cost-optimal. The impact on the spatial distribution, is minor, however, as these 5 WPPs only constitute 7% of the new wind power capacity in the baseline scenario (S1). Incorporating the biodiversity constraint (BIO) has the largest impact on the spatial distribution, disabling largely WPPs in the South that otherwise would be considered cost-optimal (the results for the two constraints are not shown separately in Fig. 2). When the biodiversity constraint is applied together with the wilderness constraint, a total of 10 wind parks are disabled out of the invested 16 in the base scenario (S1), as seen in Table 2. Of these, 8 are located in the South. To compensate for the production loss, two new, but less profitable wind parks are selected in the Central region. This is somewhat surprising considering our anticipation, in Sect. 2.4, that the wilderness and biodiversity constraints would shift WPP siting out of pristine nature areas and closer to more populated areas. The results indicate that that large pristine nature areas of importance for wilderness and biodiversity are also found in the southern parts of Norway. Nevertheless, the choice of WPPs within each of the regions indicate support for the assumption that there is a trade-off between pristine wilderness and local disamenity costs. Lastly, compared to S4, including also local disamenity costs (S5) further enhances the social profitability of WPPs in North, reducing investment in the Central region by 10%.
4.3 Energy System Surplus, Environmental Costs and Welfare Impacts of Increased Wind Power Production: Comparison Across Scenarios
In the numerical illustrations above, we considered the optimal spatial distribution of WPPs under different environmental impact constraints, given an annual production increase of 4 TWh (S1-S5). Here we explore the impact of increased wind power production on the energy system and environmental costs. In Fig. 3 and Table 3, we present the additional energy system surplus, local disamenity and carbon costs of increasing the production of wind energy by 4 TWh/year over 25 years and across the different scenarios. Figure 3 illustrates the costs and benefits in thousands of euro (k€), whereas Table 3 presents the numerical values in eurocents per kWh (c€/kWh).
The energy system surplus (ESS) represents the additional surplus (i.e., revenues minus costs) for the energy system of installing 4 TWh new wind power. ESS includes the total lifetime revenues of the new WPPs, the cost of increased wind energy production, as well as the additional grid investment costs triggered by new wind power capacity. Moreover, the spatial distribution of wind power also impacts the income of other producers of other types of power, in particular hydropower. For example, the income of hydropower producers in the North in 2040 is 14% less in S5 compared to S1, as the shift in wind power investment leads to lower electricity prices in the region.Footnote 22 Hence, the net energy system revenue includes the overall system benefits and not only the private profitability of the wind producers. By subtracting the local disamenity and carbon costs from the energy system surplus, we find the increase in pecuniary social welfare (Welfare) of increased wind power production. Note that Welfare does not include the welfare loss due to loss of land with an especially high nature value (areas that are excluded from development by the W&B constraints).
Results indicate that the baseline scenario (S1) and CC (S2) obtain the highest net ESS as these scenarios are less restrictive in terms of where WPPs can be located. The scenario which includes all environmental costs and W&B constraints (S5) has the lowest net ESS, due to less profitable WPPs and a deployment which is relegated to regions with lower electricity prices. This confirms our anticipated results as discussed in Sect. 2.4. The ESS is reduced by 6% (from 2.12 to 2.00 c€/kWh). Scenario S5 results in a lower local environmental cost than S1. Including the monetary costs of local environmental degradation and carbon costs, we find that welfare as a result of new wind power developments is only reduced by 4% (0.08 c€/kWh). Another environmental benefit of S5 compared to S1 is that S5 preserves more land areas with valuable nature than S1, as 10 of the WPPs included in S1 are excluded in S5 due to the W&B constraints. By comparing S5 with S3, we find that imposing the W&B constraints (and carbon costs) in addition to local disamenity costs, results in an extra cost of 0.10 c€/kWh [101 million euro (M€)], which we can refer to as the monetised welfare cost of the W&B constraints, as discussed in Sect. 2.4.Footnote 23 We see from Table 3 that the selected WPPs differ substantially between S3 and S5. For S5 to be socially preferable to S3, the value of protecting the valuable nature in the S3 scenario must be perceived as higher than 0.10 c€/kWh (101 M€).
Incorporating only local disamenity costs (S3) has a significant impact on the outcomes for neighbouring households. The local disamenity costs are more than halved compared to the baseline (S1). This emphasises the importance of including such costs in the WPP selection process. Furthermore, we see from Table 3 that neighbouring households face considerably higher local disamenity costs when only the W&B constraints are taken into account (S4) than if no disamenity costs are taken into account (S1). The local disamenity costs more than double when moving from S1 to S4. Although the W&B constraints lead to lower investment in southern parts of Norway, the large increase in local disamenity costs indicates that concerns for loss of wilderness and biodiversity (S4) shifts wind power production to areas with a higher population density within these regions. Consequently, the WPPs that are selected within the South region in S4 are located in areas with more households in the viewscape than those selected in S1. This indicates that there is a trade-off between concerns for the welfare loss of affected people locally and the loss of wilderness and biodiversity. However, we see that the differences between S5 and S3 in monetised environmental costs are relatively modest (0.024 c€/kWh or 24 M€). Thus, it can be argued that the benefit to society as a whole of preserving biodiversity hotspots and wilderness more than outweigh the increased local disamenity costs of affected people locally, as long as these costs are included in the optimisation problem, i.e., moving from S3 to S5.
4.4 Sensitivity Analysis
4.4.1 Effects of Alternative Local Disamenity Cost Specifications
The disamenity costs faced by people affected locally differ depending on the methodology used and the assumed cost per turbine. This section therefore addresses the impact of varying the costs of and distance from the turbines. In the DISAM < 4 km scenario, we only consider the cost of turbines for households within a 4 km radius, excluding the cost of WPPs within the viewscape further away. In this scenario, the difference in distribution of WPPs from the base scenario (S1) is minor, indicating that very few WPPs are planned within this distance. Hence, the largest impact of the local environmental cost arises from the visual disamenities further away than 4 km.
In the DISAM decay scenario, the cost that neighbouring households incur depends on their distance from the WPP, cf. Eq. (5). Households closest to the WPP incur the highest cost, while the cost diminishes as the distance increase up to 4 km. In such a distance decay scenario, WPPs in the Central region are preferred to those in the South. From these results, it follows that WPPs in the South are planned in closer proximity to households than in other regions.Footnote 24
Lastly, the DISAM double scenario assumes a doubling in the local environmental cost of each of the WPPs. As presented in Fig. 4, the distribution is almost unaffected by the increase compared to S3. The spatial distribution of WPPs is therefore more sensitive to variations in cost with distance [Eq. (5)] than a uniform increase in cost [Eq. (4)].
4.4.2 Effects of a Higher Carbon Price Path
Due to the highly uncertain development of carbon prices, a sensitivity analysis is conducted to evaluate the impact of a higher carbon price on new wind power investments. The increase in carbon price is applied to the emission cost calculations and to the European energy system. Hence, a higher electricity price for countries with transmission capacity to Norway is included in the model. To differentiate between the impact from the carbon cost of land use and the impact from changes in the European energy system, we designed two high scenarios, High CC and High Base. The High Base only includes the high carbon price path in Europe and not for the WPP emission cost calculation.
As described above, higher CO2 prices affect the results both directly through the higher carbon costs of land use changes, and indirectly through higher international electricity prices. In Fig. 5, we can observe that the change in spatial distribution is mainly caused by higher electricity prices in Europe, favourising the production and export of wind power from the southern parts of Norway. This is clear from the comparison of High Base and High CC, in which there are no differences in wind power deployment. The reason for the increase in the deployment share in the Central region for the high price scenarios is due to shorter distances to export cables compared to the North. In the Baseline and CC scenarios, the new wind power potential has already been realised in the South, making Central the region with the lowest additional cost for grid expansion. This is further confirmed by the transmission flow results, in which net exports from the Central region to the South are increased by 5.8 TWh in the CC scenario with high CO2 prices compared to the CC scenario with medium CO2 prices. Hence, the impact of the emission cost of land use on the spatial distribution seems to be limited or close to zero, regardless of the CO2 price assumptions.
4.4.3 Effects of Hard Constraint in the Form of Indigenous Reindeer Husbandry Rights
The spatial distribution of WPPs has also been assessed with respect to their interference with reindeer husbandry, see Sect. 3.2.3. This criterion is activated for WPPs with more than 1% overlap for one or more of the reindeer criteria, which disables a total of 12 WPPs out of 26. Adding this to the W&B constraints leaves us with only three WPPs as possible investment alternatives. Consequently, the production levels from new land-based wind power would reach only 1.3 TWh/year, substantially lower than the maximum target of 4 TWh/year (top bar in Fig. 6). Production would be distributed between the South and the Central regions, with no new wind capacity in the North, where reindeer husbandry is most prevalent. Hence, this constraint would have substantial and wide-reaching implications for new (and potentially some existing) WPPs if interpreted as a hard constraint, as we have done here.Footnote 25
5 Concluding Remarks
We have presented a modelling framework for taking into account various environmental concerns when selecting new wind power production plants using a pool of potential new WPPs as our starting point. An energy system model (IFE-TIMES-Norway) was used to select WPPs which maximise social welfare under various constraints in Norway. We incorporated directly into the model the estimated externality costs in the form of carbon emission costs and the local disamenity costs faced by households with WPPs in their viewscape. Impacts on wilderness and biodiversity were implemented in the model analysis as strong wilderness and biodiversity (W&B) constraints. We used the database of proposed WPP projects in Norway (NVE 2022) as the pool of potential WPPs for reaching a target of 4 TWh annual production from new wind power.
Our numerical simulations show that the environmental concerns had a significant impact on the optimal selection of WPPs across the country. In the base scenario (S1) we did not take into account any environmental impacts. Purely from an energy system perspective, the South is the most favourable region for wind power investment, showing its maximum potential in the base scenario. In the scenario where all environmental concerns were taken into account (S5), production in the South was only 40 percent of its maximum potential, and production in the North was three times higher than in scenario S1.
The impact of increased wind power production on the energy system surplus does not differ substantially across the scenarios, being 6% at the most (between S1 and S5). Hence, replacing some WPPs with others does not have a very large impact on the surplus. This implies that taking all the environmental concerns into account when selecting WPPs to be constructed is not very costly. While not directly comparable, a recent analysis from the UK in a similar vein shows that removing 10% of the most scenic areas for onshore wind power implies about an about 18% lower generation potential and 8–26% higher costs (McKenna et al. 2022).
Following the lines of Bateman and Mace (2020) regarding biodiversity as critical natural capital with limited substitutability, we did not attempt to estimate the value of impacts on wilderness and biodiversity, but rather imposed those as constraints on the model. The numerical illustration shows, somewhat surprisingly, that if the benefit to society of avoiding the development of the 10 WPPs which violate the W&B constraints exceeds 0.10 c€/kWh, the S5 scenario (all environmental costs and constraints included) is superior in terms of welfare to S3 (only local disamenity costs included). In total, this amounts to 101 million (M) €. Dividing this by the number of households in Norway (approximately 2.5 million), if preserving biodiversity and wilderness is considered a national responsibility, this amounts to around EUR 40 per household as a one-time amount. While it is not straightforward to compare this with the results of Norwegian non-market valuation studies, there are some indications that this amount is modest. For example, Lindhjem et al. (2015) found an annual WTP per household of NOK 1040-1300 (in 2007) in a contingent valuation study of the preservation of forest biodiversity at national level in Norway. This is substantially higher than the amount that would be required to satisfy the W&B constraints considered here, which are strict for the areas included in the analysis. Hence, in future analyses it may be justified to include further criteria and areas to account for stronger concerns about W&B. A recent study in two regions of Norway also showed substantial WTP among households in areas affected and unaffected by wind power to avoid a broad set of externalities (Dugstad et al. 2020).
Overall, our results show that there is a trade-off between local disamenities and loss of biodiversity and wilderness. Siting wind power plants outside the visual proximity of households yields negative consequences for biodiversity and wilderness. We conducted a comprehensive sensitivity analysis. In view of uncertainty and discussion in the literature about the local disamenity cost function (Lehman et al. 2021a; b; Grimsrud et al. 2021; Ruhnau et al. 2022), we devoted some consideration to that point. The sensitivity analysis explored the consequences of increasing the disamenity costs, the carbon costs, and adding a constraint to prevent new WPPs that violate indigenous reindeer husbandry rights.
The sensitivity analyses show that our main results are relatively robust. Increasing the local disamenity costs has only a minor impact on results, although there is a small change in terms of where the WPPs were located for the case with distance decay within 4 km. In that case, some wind power production moves from the South, where WPPs are generally located closer to residential areas, to the Central region. Increased carbon costs lead to more demand for wind power by importing countries and therefore more WPPs are sited in locations closer to the export cables. The increased carbon cost did not cause fewer WPPs to be built on mires. The sensitivity analysis also shows that if a constraint relating to indigenous reindeer husbandry rights is added in addition to constraints on wilderness and biodiversity, it is no longer possible to realise the target of 4 TWh—instead only 1.3 TWh can be produced.
However, we are aware of some caveats and potential weaknesses that may be important for our results and that we have not yet fully investigated. First, it is clear that limiting the allowable WPPs to the existing pool of concession applications is a practical decision, but a potential weakness. There may be other sites that could both increase the total generation capacity and have better profiles in terms of environmental impact. In the modelling, we also make some simplifying assumptions and do not include any form of stochasticity. For example, we assume that all WPPs are invested in 2025, while some are likely to be installed earlier and some later. We have not differentiated between those that have already obtained a concession (and are likely to be built soon) and those that are in the application process (and that have a higher probability of not being built). In future work, such points may be refined.
Second, with regard to the local disamenity costs, we admit that it may be difficult to fully differentiate between local disamenity impacts and impacts on biodiversity and wilderness more generally, as people in the viewscape may also be aware of and consider such impacts to be part of the “bundle” of disamenities they experience. However, we do believe that other impacts (such as noise, flickering lights, landscape aesthetics and reduced recreation quality), may be the most important locally (cf. e.g., Dugstad et al. 2022; Handberg et al. 2020). The more fundamental importance of biodiversity (as a building block for other services), and the reason why such impacts are considered an important constraint, may not be fully appreciated, and thus the problem of “double counting” is probably relatively small. Our assumptions regarding the local disamenitiy costs of future WPPs, based on the average specifications of turbine capacity and height in 2021, along with the assumption of uniform placement of turbines in the WPP plan area, also add uncertainties to our results.
Lastly, this analysis was performed before the energy crisis in Europe, and thus the results do not represent the current electricity price situation. With higher prices in Europe, we would expect an even larger North–South price difference, resulting in even more favourable conditions for onshore wind power in the South. The cost of including environmental concerns, i.e., moving investment in wind power to the North, would therefore likely be higher. It is also expected that households would be less reluctant to accept new wind turbines, as new, cheap power is one of the main contributors to reducing electricity prices and ensuring security of supply. Despite electricity prices reaching an all-time high, it is, however, expected that prices will ease as economies slow and markets rebalance (IEA 2022).
As the whole energy system will undergo a transition, it will also be important to consider the environmental impacts of other renewable energy sources, for example, offshore wind power and solar power, which are both scheduled for major expansions in Norway during the next decades. Replacing onshore with offshore wind power, for example, will reduce land requirements (Tröndle 2020). Finally, while we have investigated how to factor in both local and wider environmental impacts and derive more optimal spatial configurations of wind power production, it will be important to work towards regulatory instruments to internalise environmental impact in developer and regulator decisions. It is clear that in doing so it will also be important to balance efficiency and equity considerations (Weinand et al. 2022), as our results show that there may be relatively large and unequal effects across the different scenarios, especially between North and South.
Notes
Note that the symbol J has a double interpretation as it denotes the total number of WPPs as well as the ultimate WPP of the WPPs.
Electricity production, qi, will be a function of the installed capacity and the capacity factor at WPPi. The capacity factor describes the ratio of the actual power output of the WPP to its maximum power output in any given hour and is influenced by different parameters including the wind speed at the location of the WPP.
Note that in the empirical analyses in later sections, the set of new potential WPPs considered is limited to WPPs for which a concession has either been granted or for which an application is under consideration by the authorities (c.f. discussion in Sect. 2.4).
The assumption is based on a review of the cost breakdown from different concession applications in NVE’s database.
The European power prices used in this analysis do not represent the current price levels resulting from the energy crisis.
For the sake of simplicity and to avoid any issues of double counting, we do not include externalities related to the construction or upgrade of power lines, locally, regionally or nationwide. These costs are hard to estimate and normally not included in modelling studies of wind power development. An exception is Grimsrud et al. (2021), which distinguishes between local and national externalities of power lines.
WPP concession applications only indicate the total MW to be produced. To estimate the number of turbines, we divided the total MW to be produced by the average capacity per turbine in 2021, which was 5 MW.
This number has increased during the Covid pandemic, so to be more representative of a normal year, we used the average for the last five years. There is no information about how cabin owners value the disamenity impacts of wind power, so we chose this simple approximation.
This study has used a subjective wellbeing valuation approach to show that the negative effect of wind power drops substantially beyond 4 km from the WPP in Germany.
Note that the life cycle impacts of the production and transportation of turbines to Norway are not included in the carbon costs used here. The carbon content of fuel used for transport on Norwegian territory is priced higher than EU ETS carbon prices.
Norwegian authorities maintain an indicator called “INON”, which measures the size of natural and unfragmented areas of less than 1 km, 1–3 km or more than 5 km from the nearest technical installations such as roads, power lines, houses, etc.
The index is calculated as the frequency of key characteristics (in this context different types of infrastructure that involve intervention and fragmentation of areas), measured in a circle with a radius of 500 m around each pixel (focal point) and calculated for the whole country. The infrastructure index consists of two components that are added together: a building component and a constructed mainland component. The latter indicates the occurrence of constructed fixed land area, the result of interventions, which gives the landscape a 'human landscape character'). The infrastructure index is 2-logarithmic in each component, which means in principle that each doubling of the frequency of buildings and constructed fixed land, increases the value of the respective component by a constant number of units. Two components are considered not to be equally important for the landscape's utilisation character; the presence of buildings is considered to leave a stronger mark (2/3) on the landscape than the presence of land areas with infrastructure (1/3).
5% was used to account for geometric error in the data that may cause some overlap in the GIS analysis, whereas in reality there may no overlap or none of any significance. With national scale spatial data, there is always some geometric error, but the benefit of using these data (i.e., being able to evaluate all WPPs equally) outweighs the error.
Note that wild reindeer (approximately 25 000 individuals in total) is included as part of the biodiversity constraint above, while tame reindeer (roughly ten times as many) are included in this separate constraint.
Seasonal grazing areas consist of zones where the reindeer graze during spring, summer, autumn and winter.
Movement corridors are routes between seasonal grazing areas that the reindeer either migrate along or are driven along.
Staging areas are areas where reindeer are gathered for relocation, calving or slaughter.
Administrative areas («siidaområde») are managed by a family for the various reindeer activities during the year. https://register.geonorge.no/register/versjoner/produktark/landbruksdirektoratet/reindrift-siidaomrade
A sensitivity analysis revealed that there was no difference in the number of WPPs that had < 40% overlap (i.e., 48% of WPPs). A total of 37% of WPPs included in the analysis had < 75% overlap and 33% had 100% overlap with reindeer areas.
The results for average regional electricity prices in Norway for the different scenarios are presented in “Appendix B”, Figure B2.
We have ignored the impact of the minor effect of also including carbon costs in S5.
We also conducted a sensitivity analysis where the WTP per turbine decreased with the number of turbines at a site, based on a transferred estimate of scope elasticity from Dugstad et al.’s (2021) choice experiment study of a national wind power development plan with number of turbines as an attribute. Results (left out for the sake of brevity) showed marginal impacts on the spatial distribution of WPPs compared to the base case.
At the time of writing, the consequences of the Supreme Court verdict mentioned in 3.2.3 is unclear, with respect to both whether the Fosen WPP (and any other existing WPPs in violation of similar indigenous rights) must remove their turbines and restore the area or not, and whether new WPPs have to avoid all similar reindeer areas.
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Acknowledgements
The authors are grateful to senior advisor Erik Engelien at Statistics Norway for contributions on GIS analysis. We are also grateful for valuable comments from Bjart Holtsmark and two anonymous referees. The research was funded by The Norwegian Research Council, grant numbers 267909 and 319917.
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Appendices
Appendix A: Parameters for New and Existing Wind Power Plants
Appendix B: Assumptions Regarding carbon price paths
See Table 6 and Figs. 7 and 8.
Appendix C: Carbon Emission Calculations
The present values of the carbon cost components of equations in (7) are calculated as:
We assume that carbon prices will increase until 2100 and remain constant thereafter (see “Appendix B”). See Table 7 for the description of symbols, units and assigned values.
Appendix D: Wilderness and Biodiversity Constraints
See Table 8.
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Grimsrud, K., Hagem, C., Haaskjold, K. et al. Spatial Trade-Offs in National Land-Based Wind Power Production in Times of Biodiversity and Climate Crises. Environ Resource Econ 87, 401–436 (2024). https://doi.org/10.1007/s10640-023-00764-8
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DOI: https://doi.org/10.1007/s10640-023-00764-8