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Global Solar Atlas

The Global Solar Atlas is a free, web-based platform that provides high-resolution maps and on solar resource availability and photovoltaic () power potential for virtually any location on , enabling users to assess opportunities for project planning and development. Developed by the Group's Energy Sector Management Assistance Program (ESMAP) in collaboration with Solargis, the atlas was first launched in 2017 as a tool to accelerate the global scale-up of by offering accessible, reliable to governments, investors, and developers. The platform draws on satellite-derived datasets processed through Solargis' proprietary models, incorporating inputs from sources such as NOAA, , ECMWF, and , with temporal coverage from 1994 to 2024 (updated periodically; as of 2025). Its spatial resolution reaches up to 250 meters for solar and 1 kilometer for output and air estimates, covering land areas between 60°N and 55°S latitudes, encompassing approximately 120 million square kilometers. Key features include interactive maps displaying annual and monthly averages of global horizontal irradiation (GHI), direct normal irradiation (), and PV energy yield; a PV calculator for estimating system performance based on user-defined configurations; and downloadable GIS layers in formats like for advanced analysis in tools such as or . Version 2.0, released in October 2019, introduced enhancements such as higher-resolution data, potential assessments, project-saving capabilities, and expanded country-specific factsheets for 187 nations; the platform has continued to receive updates, with version 2.12 released in April 2025. The data has been validated against over 220 ground measurement stations, achieving bias standard deviations of approximately 3% for GHI and 5% for DNI, with expected uncertainties (80% occurrence) of 4-8% for GHI and 9-14% for DNI, making it suitable for preliminary site screening while recommending on-site measurements for detailed feasibility studies. A major associated output is the 2020 World Bank report Global Photovoltaic Power Potential by Country, which leverages the atlas's data to evaluate theoretical, practical, and economic potential across nations, revealing that 93% of the world's resides in countries with average daily output between 3.0 and 5.0 kWh per kilowatt-peak, and that resources could exceed current in most regions when accounting for land-use constraints. This study highlights low-seasonality hotspots suitable for 86% of the global , where annual output variations are under twofold, underscoring 's reliability for . The atlas and report together promote equitable access to intelligence, particularly in developing countries, by reducing the costs of resource assessment and fostering international partnerships like those with the and IRENA.

History and Development

Origins and Launch

The Global Solar Atlas originated as an initiative under the Group's (ESMAP), aimed at enhancing access to resources in developing regions. Developed by Solargis, a leading provider of solar data and modeling services, in collaboration with ESMAP, the project leveraged the 's funding and strategic oversight alongside Solargis's expertise in solar resource assessment. The project was launched in partnership with the (ISA) to create a dedicated platform for solar energy data, building on earlier global efforts like the 2012 Global Atlas for Solar and Wind Energy launched by the (IRENA), but with a sharpened focus on solar-specific resources to address gaps in targeted solar planning. The atlas was publicly launched on January 17, , during an event at the World Future Energy Summit in , . This debut marked a significant step in making high-resolution freely available worldwide, utilizing satellite-derived observations to ensure comprehensive coverage without reliance on ground measurements alone. From its , the primary objectives centered on accelerating the adoption of in developing countries by offering policymakers, investors, and developers easy access to reliable solar potential maps and data layers. By reducing the time and cost associated with site-specific resource assessments, the tool sought to support informed decision-making for projects and contribute to .

Key Updates and Versions

The Global Solar Atlas, initially launched in 2017, has undergone several significant updates to enhance its utility for solar resource assessment. was released in October 2019, marking a major enhancement over the original platform with improved spatial resolution of approximately 250 meters globally for solar resource maps and data layers. This update incorporated more recent satellite-derived data extending coverage up to 2018, providing long-term averages spanning over 22 years for key parameters such as global horizontal (GHI) and diffuse horizontal (DHI). Additionally, it expanded the range of meteorological parameters available, including monthly and hourly profiles for photovoltaic () power output and direct normal (DNI), alongside features like project bookmarking and downloadable reports in PDF and formats. These changes were motivated by advancements in technology and user feedback to support broader solar project planning. Subsequent minor versions, such as 2.1 and 2.2, introduced further refinements, including updated terrain data and improved simulation models for greater accuracy in resource estimation. By July 2021, version 2.6 had integrated these enhancements, maintaining the focus on high-resolution global coverage. In 2025, version 2.12 was released, updating the radiation and meteorological database to incorporate data through 2024 and extending long-term average periods (e.g., 1994–2024 in regions like ). This iteration added integrations with additional solar measurement sites for ground-validation comparisons and refined output simulations to reflect the latest temporal data. Overall, these updates have been driven by ongoing user input and technological progress, progressively expanding parameter sets such as DHI while prioritizing accuracy improvements validated against over 220 global weather stations.

Data Sources and Methodology

Input Data and Sources

The Global Solar Atlas relies on satellite-derived irradiance data as its primary input for estimating solar radiation parameters. This data is sourced from geostationary satellites, including the Meteosat series (MFG and MSG) operated by , the GOES series (East, West, and others) from NOAA, and additional satellites such as MTSAT and Himawari-8 from JMA, providing coverage primarily between 60°N and 55°S latitudes, with extensions to 45°S in and further south in regions like following recent updates. These satellites capture imagery at resolutions of 2–5 km at the , with temporal frequencies of 10–30 minutes, enabling the derivation of global horizontal (GHI), direct normal (DNI), and diffuse horizontal (DHI) through cloud index calculations based on surface radiance measurements. Meteorological auxiliary data complements the satellite inputs, drawn from reanalysis products to account for atmospheric variables affecting solar resource estimates. The European Centre for Medium-Range Weather Forecasts (ECMWF) ERA5 dataset serves as a key source, providing hourly on air temperature, wind speed, and aerosol optical depth at a global of 0.25° (approximately 28 ), integrated to support modeling of clear-sky conditions and atmospheric effects. This reanalysis spans the full temporal period of the atlas and enhances the accuracy of calculations by incorporating variables like and aerosols that influence transmission. Ground-based measurements are integrated for bias correction and of the and reanalysis inputs. The atlas incorporates from over 220 ground measurement stations worldwide, including high-quality networks such as the Baseline Surface Radiation Network (BSRN), which provide site-specific observations of GHI, , and meteorological parameters using calibrated pyranometers and pyrheliometers. These stations, with records typically spanning at least 12 months, enable site-adaptive adjustments to the modeled , reducing systematic errors in regions with sparse coverage. The temporal scope of the input data covers long-term averages from to 2023 (as of the latest update in 2024), with regional variations in start dates (e.g., for Meteosat-covered areas, 1999 for GOES, and 2007 for ). As of 2025, the database has been updated to include data up to 2023 and extended coverage in southern latitudes such as . Raw inputs include at 10–30 minute intervals, aggregated to hourly, daily, monthly, and yearly scales for practical use in assessments. This extended period allows for robust climatological analysis, capturing interannual variability in resources. Spatially, the inputs provide coverage over surfaces between 60°N and 55°S and coastal seas, with the native 2–5 km from satellites resampled to 250 m or 1 km for atlas outputs in high-potential areas. Enhanced detail is prioritized in regions like and , where solar development is accelerating, supported by denser ground station networks and refined satellite processing to better resolve local and patterns.

Computational Models and Validation

The Global Solar Atlas relies on the Solargis satellite-based model to process raw into actionable solar radiation data. This model employs physical parameterization to detect clear-sky conditions and derive the cloud index, which quantifies atmospheric attenuation primarily due to clouds. Clear-sky detection is achieved through the model, which computes irradiance adjusted for atmospheric effects such as aerosols, , and , assuming no cloud presence. The cloud index (ci) is calculated as the ratio of the measured global horizontal (GHI) to the clear-sky GHI: ci = \frac{\text{GHI}}{\text{GHI}_\text{cs}} where \text{GHI}_\text{cs} represents the clear-sky global horizontal . This index, derived from radiance in visible and channels using a modified Cano , enables the estimation of actual surface by scaling clear-sky values. To further decompose GHI into direct normal (DNI) and diffuse horizontal (DHI), the model applies empirical separation techniques, including the Dirindex model for DNI estimation and the Perez model for diffuse components on tilted surfaces. These steps ensure separation of beam and scattered radiation components essential for diverse applications. Photovoltaic power potential is assessed through specific photovoltaic output (PVOUT), expressed in kWh/kWp, which represents long-term per unit of installed . PVOUT is computed as a function of GHI, , air temperature, and system losses using Solargis PV simulation algorithms. The calculation incorporates global tilted (GTI) derived from direct and diffuse components, adjusted for optimal tilt angles, module temperature effects, and standardized losses such as soiling, inverter inefficiency (typically 2-7%), and overall system (default ~8.9% for fixed-tilt systems with module efficiencies around 15-20%). Terrain shading and angular reflectivity are also factored in for site-specific accuracy. Validation of these models involves rigorous cross-comparison with ground-based measurements from over 228 high-quality stations worldwide, using Class A pyranometers for GHI and Class B pyrheliometers for , with data spanning at least 12 months after . Results indicate average monthly error (RMSE) of 3.8% for GHI across diverse zones, achieving <5% in many validated areas, while hourly RMSE averages 16.8%. maps are generated for each parameter, showing GHI uncertainties of ±4.0% to ±8.0% at 80% occurrence probability, with higher values in tropical and high-aerosol regions; DNI uncertainties range from ±9.0% to ±14.0%. These assessments confirm the model's reliability for global-scale applications. The processing pipeline operates at a of 10-30 minutes, derived from geostationary observations (e.g., 15 minutes for Meteosat), before aggregation into hourly, daily, monthly, and annual summaries. This upscaling preserves long-term averages (1994-2023) while minimizing interpolation errors through physical and empirical corrections.

Core Features

Interactive Tools and Visualization

The Global Solar Atlas provides a web-based GIS viewer as its primary interactive tool, enabling users to explore global through a zoomable map that covers the entire world at resolutions of 250 meters and 1 kilometer. This map supports layered overlays for key solar parameters, including global horizontal (GHI), direct normal (DNI), photovoltaic power output (PVOUT), and optimum tilt angles (OPTA), allowing seamless switching between datasets to assess potential across regions. Users can search by location name or coordinates and zoom to specific areas for detailed , with the interface designed for intuitive navigation without requiring specialized software. Customization options enhance user-defined analysis, permitting the selection of single points, rectangles, or polygons on the to generate site-specific insights. For these selections, the tool displays annual averages and detailed metrics, such as time-series graphs showing 12-month by 24-hour hourly profiles, as well as seasonal variations through monthly PVOUT data. Regional analyses for polygons include statistical summaries like minimum, maximum, and values, facilitating comparative assessments of solar viability over larger areas. These features derive from Solargis computational models to ensure accuracy in presented visuals. Visualization employs color-coded heatmaps to represent intuitively, for instance, GHI from 0 to 2500 kWh//year with graduated colors indicating intensity. Users can adjust display parameters, such as map resolution or parameter focus, and export visualizations as high-resolution images ( or formats), PDF reports, or Earth-compatible KML files for further use in presentations or planning. This export functionality supports both site-specific and regional outputs, including customizable project summaries. Additional integrated tools include an optimum tilt calculator, which recommends fixed tilt and angles based on and local conditions to maximize energy yield, and a shadow that quantifies terrain-induced losses as a (ranging from 0% to 10%). These tools operate directly within the , providing immediate on factors. The emphasizes , offering free use without requirements for functionalities, and features a mobile-responsive introduced in to support on-the-go analysis across devices.

Data Access and Outputs

The Global Solar Atlas provides users with various download options for accessing solar resource and photovoltaic potential data, including gridded datasets in and formats for global coverage or regional subsets, as well as time-series data in format for specific custom locations. These outputs focus on long-term averages up to (as of version 2.12 released in April 2025), encompassing key parameters such as global horizontal irradiation (GHI), direct normal irradiation (), diffuse horizontal irradiation (DHI), air (TEMP), and photovoltaic power output (PVOUT) for both fixed-tilt and tracking systems. Additional parameters include (ELE) and optimum tilt (OPTA), with time-series profiles available as 12 monthly by 24 hourly breakdowns for select metrics like PVOUT and . Data is offered at multiple resolution tiers to balance detail and coverage, with a global standard of approximately 250 meters (9 arcseconds) for core solar irradiation parameters (GHI, , DHI), and 1 kilometer (30 arcseconds) for PVOUT, , and elevation data. Users can preview these outputs via visualizations prior to download to ensure relevance. All data outputs are released as open resources under the Attribution 4.0 International (CC BY 4.0) license, permitting free use, sharing, and adaptation for any purpose, including commercial applications, provided proper attribution is given to the and Solargis. in PDF and XML formats accompanies downloads, adhering to ISO 19115 standards, to support data integrity and usage documentation.

Applications and Impact

Use in Policy and Planning

The Global Solar Atlas plays a pivotal role in national planning by enabling governments to identify high-potential zones for development, thereby supporting the establishment of targets. For instance, in , it has aided by providing high-resolution solar resource maps that overlay like transmission lines and protected areas, facilitating informed decisions on solar park locations. This tool offers GIS data layers for over 180 countries, allowing planners to assess photovoltaic () output potential at a 1 km resolution, which streamlines the prioritization of regions with optimal for large-scale deployments. Integration of the Global Solar Atlas into broader policies has been widespread, with its data utilized in over 100 countries for designing feed-in tariffs and conducting grid integration studies. It is frequently cited in authoritative reports, such as those from the (IRENA), where resource assessments draw on its validated datasets to evaluate national renewable strategies and economic viability. By providing harmonized global data, the atlas supports policy frameworks that align expansion with grid stability requirements, reducing uncertainties in long-term energy modeling. Capacity building efforts leverage the Global Solar Atlas through and ESMAP programs, which offer training and interpretive guides for policymakers, particularly in and , to analyze specific outputs like photovoltaic power (PVOUT) for and designs. These initiatives, including online tools and user manuals, equip decision-makers with skills to translate solar resource maps into actionable policy measures, fostering regional expertise in renewable integration. In economic analysis, the atlas's resource maps facilitate cost-benefit evaluations by incorporating (LCOE) estimates tailored to country-specific conditions, aiding preliminary feasibility studies. This has demonstrated value in lowering project risks and exploration expenses by minimizing the reliance on costly on-site measurements, with examples showing substantial reductions in upfront costs for potential sites. On a global scale, the Global Solar Atlas contributes to Sustainable Development Goal 7 by mapping solar potential to enhance energy access in underserved regions, while its data informs climate pledges under the through IRENA's renewable potential evaluations. As of 2024, the platform's solar radiation and meteorological database was updated to include data from 2023, supporting ongoing policy development and investment decisions worldwide. These applications underscore its role in advancing decarbonization efforts worldwide.

Project Development and Case Studies

The Global Solar Atlas has played a key role in utility-scale project development by providing high-resolution for site screening and layout optimization. For (CSP) facilities in regions with high direct normal irradiation (), such as , the tool's maps support early-stage feasibility assessments. For rooftop and distributed solar applications, the Atlas supports urban potential assessments by combining photovoltaic output (PVOUT) estimates with building footprint data. In , analyses utilizing the platform have informed strategies amid the country's rapid solar market growth. Case studies highlight the Atlas's impact on project timelines and efficiency. In , the tool has supported the Independent Power Producer Procurement Programme (REIPPPP) by providing yield forecasts for grid-connected farms in high-potential regions. Investors rely on the Atlas for bankability evaluations, exporting time-series data on global horizontal irradiation (GHI), , and PVOUT for integration into financial models. For instance, outputs are commonly fed into the National Renewable Energy Laboratory's System Advisor Model () to simulate cash flows, levelized costs, and debt service coverage ratios, aiding for financing ventures. This interoperability enhances project viability reports, with users accessing downloadable GIS layers for site-specific economic projections. On the international front, the Atlas underpins collaborative efforts like the International Solar Alliance's (ISA) One Sun One World One Grid initiative, which promotes cross-border solar integration. By offering harmonized resource maps, it enables alignment of development plans across regions, such as linking high-irradiance zones in and for transnational grid interconnections and shared infrastructure investments.

Limitations and Future Directions

Current Constraints

The Global Solar Atlas operates at a spatial resolution of approximately 250 meters, which captures broad regional solar resource patterns but proves insufficient for precise micro-siting in complex terrains such as mountainous or urban areas with significant shadowing effects. This limitation introduces uncertainties of around ±9% for global horizontal irradiation (GHI) and ±16% for direct normal irradiation (DNI) in shadowed or topographically varied locations, where local microclimates deviate from the modeled averages. As a result, users must supplement Atlas data with higher-resolution site-specific assessments for detailed project planning. Data coverage in the Global Solar Atlas is constrained by its reliance on satellite observations, with historical records beginning in 1994 for most regions, 1999 for others, and 2007 in select areas, leaving pre-1994 periods unaddressed or reliant on less accurate extrapolations. The database was extended to include data up to 2024 as of May 2025. Accuracy diminishes in polar regions due to suboptimal satellite viewing angles and limited orbital coverage, with the dataset effectively restricted to latitudes between 60°N and 55°S and only sparse validation available at high latitudes. Parameter estimates in the Atlas, particularly photovoltaic output (PVOUT), do not incorporate updates, instead providing long-term averages that exclude localized factors such as panel soiling, vegetation shading, or electrical grid integration constraints. These omissions stem from the model's focus on standardized global simulations, potentially underestimating losses by 2-5% in dusty or networked environments without additional user inputs. Validation of the Atlas relies on comparisons with ground measurements from approximately 320 public stations worldwide, but sparse station density in remote, developing, or arid regions leads to higher error (RMSE) values exceeding 7% for (DNI) in unvalidated zones. Monthly DNI RMSE averages around 9% globally, rising in areas lacking nearby reference sites due to the challenges of maintaining in harsh conditions. Accessibility to the Atlas's interactive tools demands a stable connection for web-based and , limiting utility in low-connectivity areas common to developing regions. While offline data downloads are available in GIS formats such as and shapefiles, processing these requires specialized software and expertise in geographic information systems, posing barriers for non-technical users or organizations without dedicated resources.

Ongoing Developments

As of May 2025, version 2.12 of the was released, updating the solar radiation and meteorological database to include data from 2024.