1. Introduction
Demand for energy is likely to rise greatly by mid-century due to a growing global population, increased per capita energy consumption (correlated with affluence), and electrification of transport, heating, and industry. There is an urgent need to reduce carbon emissions to address the intensifying climate crisis. This challenge requires solutions that can not only fulfill increasing energy needs but also contribute to zero-carbon targets. The leading solution is solar PV technology, with support from wind energy. In 2022, more new solar PV [
1] generation capacity was installed than everything else combined.
The International Energy Agency (IEA) projects that the world’s electricity demand will grow to around 60,000 terawatt-hours (TWh) by 2050 compared to current levels [
2], even after considering increased energy efficiency measures. The International Renewable Energy Agency (IRENA) projects that world electricity generation will nearly double to about 50,000 TWh in 2050 [
3]. Typical per capita electricity consumption in developed economies is 6–12 megawatt-hours (MWh) per person [
4]. This may double to around 20 MWh per capita [
5] to accommodate electrification of most energy functions. According to the United Nations, the world population is expected to approach ten billion people by 2050 [
6]. Thus, global electricity demand may eventually approach 200,000 TWh per annum.
The power and area of solar panels required to supply 20 MWh of electricity per capita per annum are 14 kilowatts (kW) and 70 m
2, respectively, assuming an average capacity factor of 16% [
7] and an array solar conversion efficiency of 20%. For ten billion people, this amounts to 140 TW and 0.7 million km
2, respectively. This can be compared with the global land surface area of 150 million km
2 and the area devoted to agriculture of 50 million km
2 [
8].
The simple calculation above shows that the world has sufficient land area to provide energy from solar PV for ten billion affluent people. However, in some regions, there are constraints on provision of sufficient solar energy. These include small countries, regions at high latitudes, regions with high population density, and regions with large fractions of protected land that are unavailable for energy infrastructure. In many such regions, wind energy can provide large fractions of required energy. For example, offshore wind [
9] in the Sea of Japan, the North Sea, and the Northwest Atlantic Ocean has immense potential. Strong interregional transmission helps to cover shortfalls in solar or wind availability by smoothing out local energy demand and renewable energy supply over large areas.
Floating solar panels have the potential to provide very large-scale energy in some regions. Floating solar, also known as floatovoltaics, involves installing solar panels on floating structures on bodies of water (
Figure 1). The panels can be floated on inland lakes, artificial reservoirs, quarry lakes, or irrigation canals. Additionally, they can be located in maritime areas that are not subject to excessive wind speeds or wave heights. Floating solar PV (FPV) can have advantages over land-based systems, such as reduced land requirements, higher energy yield due to the cooling effect of water [
10], and potential synergies with existing water infrastructure [
11].
Applications of FPV systems in freshwater environments have been discussed widely. Limitations on freshwater floating solar PV systems include availability of water bodies, conflict with alternative water uses, and potential environmental impacts.
Offshore floating solar PV is an attractive option for large-scale solar energy production in some regions. Constraints include salt rather than fresh water, strong winds and large waves in many regions, and conflict with fisheries and environmental values. However, there is vast potential for maritime FPV because seas and oceans are very large. In many of the world’s densely populated areas, electricity demand centres are located close to coastal regions. Approximately 40% of the world’s population lives within 100 km of coastal regions [
13].
To date, limited research has been conducted on assessing the suitability of ocean surfaces for floating solar PV sites. This study addresses this research gap by assessing the potential of ocean surfaces for floating solar PV sites. Preferable places for maritime solar panels are those where maximum wave heights and wind speeds are low because this reduces the cost of the engineering defences required to protect the panels.
In this study, a set of 40 years of maximum hourly wind speed and wave height data was analysed to map the preferable sites for floating solar PV. The largest wave heights and wind speeds experienced during the years 1980 to 2020 were selected to characterise suitability, since it is maximum values that drive the cost of engineering defences. The ocean’s surface covers 363 million km
2, which is about 72% of the earth’s surface [
14]. The scope of this research encompasses sea and ocean surfaces within 300 km of land. The analysis is conducted at a spatial resolution of 11 km to provide an assessment of the potential for maritime floating solar PV sites. This study is the first comprehensive survey of the scope required for maritime floating solar PV that considers factors such as hourly maximum wave height and hourly maximum wind speed. This study is not concerned with developing new floating solar PV technology.
3. Methodology
Our aim is to provide a comprehensive resource assessment of maritime floating PV systems, taking account of wind speeds, wave heights, protected waters, distance from land, and territorial considerations. We evaluated global ocean surface wind and wave characteristics from 60 degrees North to 60 degrees South using hundreds of thousands of 0.1-degree latitude and longitude cells, which is about 11 km × 11 km at the equator.
Hourly wind speeds and individual maximum wave heights were derived from 40 years (1980–2020) of ECMWF-ERA5 reanalysis data. The wind speed data is arranged in an 11 km × 11 km grid format. The u-component and v-component of wind speeds at 10 m above water level, representing the horizontal speed of air moving eastward and northwards, respectively, were obtained. Wind speed was calculated hourly using the formula in
Figure 3, with the maximum value selected for each hour.
Maximum individual wave heights, estimates of the highest wave within a 20 min time window, were derived from the ECMWF-ERA5 reanalysis data [
35]. The maximum hourly wave height data in metres was classified into five ranges: 0–4, 4–6, 6–8, 8–10, and >10. The maximum wind speeds, in metres per second, were classified into five ranges: 0–5, 5–10, 10–15, 15–20, and >20.
These data were then combined at the nearest wind speed and wave height grid point for each sea location and visualised using QGIS to create a wind–wave map, focusing on maximum rather than average wave heights and wind speeds.
Tropical storms (cyclones, hurricanes, and typhoons) are likely to cause extensive damage to maritime FPV systems that are not protected by expensive engineering defences. We used 40 years of data (1980–2020) from the International Best Track Archive for Climate Stewardship (IBTrACS) [
36,
37,
38,
39] to overlay the area of the sea impacted by tropical storms. The main storm belts are illustrated in
Figure 4. This comprehensive global collection of tropical storms, provided by the National Center for Environmental Information [
40], helped identify areas that have experienced storms and are therefore considered to be less suitable for FPV.
Maritime locations were attributed to countries based on the 200 nautical mile limit from their coastlines using the EEZ shapefile provided by the Flanders Marine Institute [
42], in accordance with international maritime law. Protected marine and coastal areas were removed from consideration using the May 2023 release of the World Database on Protected Areas (WDPA) [
43].
Figure 5 shows an overview of the methodologies implemented in this research.
4. Results and Discussion
Most of the world’s maritime areas have experienced waves larger than 10 m and wind speeds larger than 20 m/s at sometime over the past 40 years. However, some regions have not, and these became the focus of our study. Our study focused on five main areas: the seas of Southeast Asia (I); the Red Sea and Persian Gulf (II); the Mediterranean and Black Seas (III); equatorial Africa (IV); and South America (V); as shown in
Figure 6. Also included in
Figure 6 are historical tropical storm tracks (represented by red lines).
Generally, the most suitable maritime regions for floating PV systems are located in equatorial countries due to their relatively low winds and small waves. Such areas can be found in the seas around Africa and Southeast Asia. Despite its equatorial location, northern South America experiences larger waves than other equatorial regions.
The global mapping of wind and wave conditions in these areas is illustrated in
Figure 7, while
Table 1 summarizes the global maritime floating solar PV potential. Subsequent figures show individual regions in greater detail. In the figures, a heat map colour key is used (
Table 1). Red areas are best (calmer) followed by orange, yellow, and green, while blue areas are the stormiest. Pale blue corresponds to maritime areas far from land that were not considered in this analysis. Purple areas represent marine protected areas. The dark gray line shows the history of tropical storms.
4.1. Southeast Asia (Region I)
The world’s most suitable region for maritime floating PV systems is in Southeast Asia. Malaysia, Singapore, Brunei Darussalam, Papua New Guinea, and Indonesia possess large potential for the deployment of floating PV technology. Notably, Indonesia possesses very large areas of calm sea in and around the islands, as discussed in our previous work [
44]. Indonesia is the world’s only large tropical archipelago.
Figure 8 depicts the potential of the Southeast Asian maritime area for floating PV. The figure shows that ideal locations for deploying floating panels are abundant throughout Indonesian territory. Based on historical data on tropical storms over the past 40 years [
36], we found that the maritime region extending from the southern part of Indonesia to northern Australia frequently experiences intense tropical storms. A similar situation is observed in the northern part of Indonesia, the Philippines, Thailand, Vietnam, and regions further north.
Table 2 (and subsequent tables) provides a compilation of results for each of the 25 combinations of maximum wind speeds and wave heights. The areas analysed include regions within 200 nautical miles (370 km) of the coast and exclude protected areas. The three numbers within each cell are (from top to bottom): (i) the area (in thousands of km
2); (ii) the potential solar power (in TW); and (iii) the potential annual solar generation (in thousands of TWh). For simplicity, we assume that solar panels have low (10 degree) tilt and are densely packed to yield 0.2 GW of solar power per km
2. We apply a capacity factor according to an approximate average [
7] for each region for low-tilt panels—in this case 15%—to calculate potential annual energy yield. Dark blue cells (>10 m wave height, >20 m/s wind speed) are not included in these calculations.
The numbers in each cell are necessarily approximate. The purpose is to provide perspective. As noted in the introduction, an affluent society drawing all its energy from solar PV may require around 20 MWh per person per year, which amounts to 1000 TWh per 50 million people. Thus, the number 39 in the cell (<4 m, 5–10 m/s) is sufficient for 2 billion affluent people. The combined population of the relevant countries (Malaysia, Singapore, Brunei Darussalam, Papua New Guinea, and Indonesia) is 0.33 billion people.
Indeed, Southeast Asia has 800,000 km2 of seascape that, in 40 years, has not experienced waves larger than 4 m or winds stronger than 15 m/s. This could generate about 210,000 TWh of electricity per year. This is sufficient for solar energy to provide the full energy requirements of 10 billion affluent people, which is equivalent to the projected global population in 2050. Any perception that these countries will have difficulty meeting their future energy needs from solar energy without severe conflict with food production and ecosystems is misplaced.
4.2. The Middle East (Region II)
The Red Sea and Persian Gulf have not experienced tropical storms. The Persian Gulf, enclosed by several Middle Eastern countries, covers an area of about 241,000 km
2 [
45]. The Red Sea, situated between Africa and Asia, has a surface area of approximately 450,000 km
2 [
46]. Most of the Red Sea experiences maximum wind speeds in the range of 10–15 m/s. In the Persian Gulf, about half of the area exhibits maximum wind speeds of 10–15 m/s, while the remaining half reaches wind speeds of 15–20 m/s. The entire surface of the Red Sea has a maximum wave height of 6–8 m, like most of the Persian Gulf, except for a minor portion that records a maximum wave height of 8–10 m. Overall, both regions typically experience maximum individual wave heights below 8 m and maximum wind speeds below 15 m/s, as represented by
Figure 9 and
Table 3. The maritime regions of the Gulf of Aden, situated between Yemen and Somalia, as well as the southern Arabian Sea near Oman, regularly experience storms.
The Arabian Peninsula has excellent wind and solar resources, and so it is questionable whether floating PV in the Red Sea or Persian Gulf will be required.
4.3. The Mediterranean and Black Sea (Region III)
The Mediterranean Sea and the Black Sea are located at the southern edge of Europe, which has a high population density and a northerly latitude. It would be advantageous if substantial capacity for floating PV were available to supplement land-based PV and the immense offshore wind resources in the North, Irish, and Baltic Seas.
Nearly all areas of the Mediterranean and Black Seas experience large waves of more than 10 m, although tropical storms do not penetrate this far north. Protected regions such as the northern Adriatic and the Greek Isles, as shown by
Figure 10, offer scope for floating PV systems that have engineering defences sufficient to withstand waves up to 10 m in height. About 29,000 TWh per annum (
Table 4) could be generated in such systems if they could also survive wind speeds of up to 20 m/s (assuming a capacity factor of 14%). Such systems would need to compete economically with land-based PV in southern Europe and northern Africa.
4.4. Africa (Region IV)
Equatorial Africa has enormous scope for floating PV (
Table 5). There is potential for 11,000 TWh of floating solar generation from regions that do not experience waves larger than 4 m in height or winds stronger than 15 m/s (
Figure 11). This is enough for 550 million affluent people—about one third of Africa’s current population. If the tolerable maximum wave height is 6 m, then the available resource increases to 300,000 TWh per annum, which is enough for 15 billion affluent people. It is notable that the open sea in the Gulf of Guinea does not experience large waves.
Floating PV has the potential to reduce land use conflicts. Countries bordering the Gulf of Guinea are experiencing large population growth rates. Nigeria is projected to reach 377 million people in 2050 [
47] and become the world’s third most populous country. It already has one of the highest population densities [
48] in Africa, at 250 people per km
2. In 2050, 377 million affluent Nigerians could generate 7500 TWh per annum, sufficient for all their energy needs, from 6 TW of floating PV covering 30,000 km
2 of Nigeria’s territorial seas.
4.5. South America (Region V)
The northern half of South America experiences gentle winds; about 28 thousand km
2 of seascape does not experience winds stronger than 15 m/s (
Table 6). However, Central America is subject to frequent tropical storms, while almost the entire South American coastline is subject to large waves (>10 m), as shown in
Figure 12. Offshore floating PV in Central and South America is unlikely to be an economical proposition because of the need for extensive and expensive engineering defences.
5. Conclusions
A global assessment of suitable maritime areas for the installation of offshore floating PV systems has been conducted, considering maximum wind speeds, maximum wave heights, protected areas, and territorial considerations. Maximum wave height and wind speeds over 40 years (1980–2020) were utilised.
Most of the global seascape experiences waves larger than 10 m and winds stronger than 20 m/s. The engineering defences required for floating PV under such conditions may render them uneconomic compared with land-based solar and wind turbines (both onshore and offshore). However, in some areas, offshore floating PV is potentially an important component of a 100% renewable energy future.
The most prospective regions cluster within 5–12 degrees of latitude of the equator, principally in and around the Indonesian archipelago and in the Gulf of Guinea in the vicinity of Nigeria and neighbouring countries. These regions have low potential for wind generation, high population density, rapid growth in both population and energy consumption, and substantial intact ecosystems that should not be cleared for solar farms.
The economical scope for offshore floating PV in Central and South America is limited by tropical storms and large waves. The Middle East has large technical potential, although there will be strong competition from land-based solar and wind farms. Europe has some prospects in sheltered areas, such as the northern Adriatic Sea and around the Greek Isles.
The combined offshore floating solar PV annual generation potential for regions that do not experience waves larger than 4 m or winds stronger than 15 m/s is 220,000 TWh. This is sufficient for all the energy needs of an affluent global population of 11 billion people. If maximum wave heights of 6 m can be tolerated, then the annual energy generation potential rises to about one million TWh as an upper bound.
The analysis and conclusions presented in this paper depend on the accuracy of meteorological reanalysis. Further work is required to ensure that the ERA5 data really does capture the historically largest waves and strongest winds. Additionally, tsunamis could be a significant risk in some areas. Finally, some maritime areas may be excluded because of their impact on fishing, navigation, the expansion of protected areas, and other factors.