Data are taken from the Microgeneration Certification Scheme - MCS Installation Database.

For enquiries concerning this table email fitstatistics@energysecurity.gov.uk.

In 2024, net solar power generation in the United States reached its highest point yet at 218.5 terawatt hours of solar thermal and photovoltaic (PV) power. Solar power generation has increased drastically over the past two decades, especially since 2011, when it hovered just below two terawatt hours. The U.S. solar industry In the United States, an exceptionally high number of solar-related jobs are based in California. With a boost from state legislation, California has long been a forerunner in solar technology. In the second quarter of 2024, it had a cumulative solar PV capacity of more than 48 gigawatts. Outside of California, Texas, Florida, and North Carolina were the states with the largest solar PV capacity. Clean energy in the U.S. In recent years, solar power generation has seen more rapid growth than wind power in the United States. However, among renewables used for electricity, wind has been a more common and substantial source for the past decade. Wind power surpassed conventional hydropower as the largest source of renewable electricity in 2019. While there are major environmental costs often associated with the construction and operation of large hydropower facilities, hydro remains a vital source of electricity generation for the United States.

Between 2010 and 2023, the average installed cost of photovoltaics worldwide declined steadily due to the widespread availability of materials, which reduced production expenses. In 2023, the average installed cost of solar PV systems stood at *** U.S. dollars per kilowatt. Likewise, the levelized cost of electricity (LCOE) for solar photovoltaics has seen a similar trend over the past decade. Solar photovoltaic technology Solar cells, also known as photovoltaic (PV) cells, can absorb sunlight and convert it into electrical energy. They are made of different semiconductor materials with specific characteristics. Silicon as the primary semiconductor has a maximum theoretical efficiency at around ** percent, this has prompted researching new materials and designs to enhance PV performance. Currently, China is by far the leading producer of solar PV modules across the globe. Solar PV energy worldwide In 2023, solar PV accounted for *** percent of the global electricity generation, with the renewables being dominated by hydropower. Despite fossil fuels remaining the largest contributor to electricity generation representing some ** percent of the global share, renewable sources are projected to grow in the following years, accounting for more than **** of the world’s power generation by 2050.

Solar Footprints in CaliforniaThis GIS dataset consists of polygons that represent the footprints of solar powered electric generation facilities and related infrastructure in California called Solar Footprints. The location of solar footprints was identified using other existing solar footprint datasets from various sources along with imagery interpretation. CEC staff reviewed footprints identified with imagery and digitized polygons to match the visual extent of each facility. Previous datasets of existing solar footprints used to locate solar facilities include: GIS Layers: (1) California Solar Footprints, (2) UC Berkeley Solar Points, (3) Kruitwagen et al. 2021, (4) BLM Renewable Project Facilities, (5) Quarterly Fuel and Energy Report (QFER)Imagery Datasets: Esri World Imagery, USGS National Agriculture Imagery Program (NAIP), 2020 SENTINEL 2 Satellite Imagery, 2023Solar facilities with large footprints such as parking lot solar, large rooftop solar, and ground solar were included in the solar footprint dataset. Small scale solar (approximately less than 0.5 acre) and residential footprints were not included. No other data was used in the production of these shapes. Definitions for the solar facilities identified via imagery are subjective and described as follows: Rooftop Solar: Solar arrays located on rooftops of large buildings. Parking lot Solar: Solar panels on parking lots roughly larger than 1 acre, or clusters of solar panels in adjacent parking lots. Ground Solar: Solar panels located on ground roughly larger than 1 acre, or large clusters of smaller scale footprints. Once all footprints identified by the above criteria were digitized for all California counties, the features were visually classified into ground, parking and rooftop categories. The features were also classified into rural and urban types using the 42 U.S. Code § 1490 definition for rural. In addition, the distance to the closest substation and the percentile category of this distance (e.g. 0-25th percentile, 25th-50th percentile) was also calculated. The coverage provided by this data set should not be assumed to be a complete accounting of solar footprints in California. Rather, this dataset represents an attempt to improve upon existing solar feature datasets and to update the inventory of "large" solar footprints via imagery, especially in recent years since previous datasets were published. This procedure produced a total solar project footprint of 150,250 acres. Attempts to classify these footprints and isolate the large utility-scale projects from the smaller rooftop solar projects identified in the data set is difficult. The data was gathered based on imagery, and project information that could link multiple adjacent solar footprints under one larger project is not known. However, partitioning all solar footprints that are at least partly outside of the techno-economic exclusions and greater than 7 acres yields a total footprint size of 133,493 acres. These can be approximated as utility-scale footprints. Metadata: (1) CBI Solar FootprintsAbstract: Conservation Biology Institute (CBI) created this dataset of solar footprints in California after it was found that no such dataset was publicly available at the time (Dec 2015-Jan 2016). This dataset is used to help identify where current ground based, mostly utility scale, solar facilities are being constructed and will be used in a larger landscape intactness model to help guide future development of renewable energy projects. The process of digitizing these footprints first began by utilizing an excel file from the California Energy Commission with lat/long coordinates of some of the older and bigger locations. After projecting those points and locating the facilities utilizing NAIP 2014 imagery, the developed area around each facility was digitized. While interpreting imagery, there were some instances where a fenced perimeter was clearly seen and was slightly larger than the actual footprint. For those cases the footprint followed the fenced perimeter since it limits wildlife movement through the area. In other instances, it was clear that the top soil had been scraped of any vegetation, even outside of the primary facility footprint. These footprints included the areas that were scraped within the fencing since, especially in desert systems, it has been near permanently altered. Other sources that guided the search for solar facilities included the Energy Justice Map, developed by the Energy Justice Network which can be found here:https://www.energyjustice.net/map/searchobject.php?gsMapsize=large&giCurrentpageiFacilityid;=1&gsTable;=facility&gsSearchtype;=advancedThe Solar Energy Industries Association’s “Project Location Map” which can be found here: https://www.seia.org/map/majorprojectsmap.phpalso assisted in locating newer facilities along with the "Power Plants" shapefile, updated in December 16th, 2015, downloaded from the U.S. Energy Information Administration located here:https://www.eia.gov/maps/layer_info-m.cfmThere were some facilities that were stumbled upon while searching for others, most of these are smaller scale sites located near farm infrastructure. Other sites were located by contacting counties that had solar developments within the county. Still, others were located by sleuthing around for proposals and company websites that had images of the completed facility. These helped to locate the most recently developed sites and these sites were digitized based on landmarks such as ditches, trees, roads and other permanent structures.Metadata: (2) UC Berkeley Solar PointsUC Berkeley report containing point location for energy facilities across the United States.2022_utility-scale_solar_data_update.xlsm (live.com)Metadata: (3) Kruitwagen et al. 2021Abstract: Photovoltaic (PV) solar energy generating capacity has grown by 41 per cent per year since 2009. Energy system projections that mitigate climate change and aid universal energy access show a nearly ten-fold increase in PV solar energy generating capacity by 2040. Geospatial data describing the energy system are required to manage generation intermittency, mitigate climate change risks, and identify trade-offs with biodiversity, conservation and land protection priorities caused by the land-use and land-cover change necessary for PV deployment. Currently available inventories of solar generating capacity cannot fully address these needs. Here we provide a global inventory of commercial-, industrial- and utility-scale PV installations (that is, PV generating stations in excess of 10 kilowatts nameplate capacity) by using a longitudinal corpus of remote sensing imagery, machine learning and a large cloud computation infrastructure. We locate and verify 68,661 facilities, an increase of 432 per cent (in number of facilities) on previously available asset-level data. With the help of a hand-labelled test set, we estimate global installed generating capacity to be 423 gigawatts (−75/+77 gigawatts) at the end of 2018. Enrichment of our dataset with estimates of facility installation date, historic land-cover classification and proximity to vulnerable areas allows us to show that most of the PV solar energy facilities are sited on cropland, followed by arid lands and grassland. Our inventory could aid PV delivery aligned with the Sustainable Development GoalsEnergy Resource Land Use Planning - Kruitwagen_etal_Nature.pdf - All Documents (sharepoint.com)Metadata: (4) BLM Renewable ProjectTo identify renewable energy approved and pending lease areas on BLM administered lands. To provide information about solar and wind energy applications and completed projects within the State of California for analysis and display internally and externally. This feature class denotes "verified" renewable energy projects at the California State BLM Office, displayed in GIS. The term "Verified" refers to the GIS data being constructed at the California State Office, using the actual application/maps with legal descriptions obtained from the renewable energy company. https://www.blm.gov/wo/st/en/prog/energy/renewable_energy https://www.blm.gov/style/medialib/blm/wo/MINERALS_REALTY_AND_RESOURCE_PROTECTION_/energy/solar_and_wind.Par.70101.File.dat/Public%20Webinar%20Dec%203%202014%20-%20Solar%20and%20Wind%20Regulations.pdfBLM CA Renewable Energy Projects | BLM GBP Hub (arcgis.com)Metadata: (5) Quarterly Fuel and Energy Report (QFER) California Power Plants - Overview (arcgis.com)

In this dataset the anther's analysis is based on data from NREL about Solar & Wind energy generation by operation areas.

NASA Prediction of Worldwide Energy Resources

Solar

Monthly averages for global horizontal radiation over 22-year period (Jul 1983

• Jun 2013)

Wind

Monthly average wind speed at 50m above the surface of earth over a 30-year period (Jan 1984 - Dec 2013)Year: Averaged Over 10 to 15 years

COA = central operating area.

EOA = eastern operating area.

SOA = southern operating area.

WOA = western operating area. Source: NRELSource Link

Snapshot img

Solar Panels Market Size 2025-2029

The solar panels market size is forecast to increase by USD 60.1 billion, at a CAGR of 8.2% between 2024 and 2029.

The market is witnessing significant growth, driven by increasing investments in the renewable energy sector. This trend is fueled by governments and businesses worldwide seeking to reduce carbon emissions and promote sustainable energy solutions. Another key driver is the continuous advancements in thin-film solar photovoltaic (PV) modules, making solar energy more cost-effective and accessible. However, the intermittent nature of solar power poses a significant challenge. Solar energy production depends on sunlight availability, which can be unpredictable. This variability necessitates efficient energy storage solutions and smart grid management systems to ensure a consistent energy supply. Companies in the market must focus on developing innovative technologies to address this challenge and capitalize on the growing demand for renewable energy. By investing in research and development, collaborating with energy storage providers, and optimizing solar panel designs, companies can effectively navigate this market landscape and seize opportunities for growth.

What will be the Size of the Solar Panels Market during the forecast period?

Explore in-depth regional segment analysis with market size data - historical 2019-2023 and forecasts 2025-2029 - in the full report.
Request Free SampleThe market continues to evolve, driven by technological advancements and expanding applications across various sectors. Off-grid systems, once a niche application, are increasingly gaining traction as an alternative power solution. Thin-film solar panels, with their flexibility and lower manufacturing costs, are finding new uses in solar powered appliances and buildings. Silicon wafer technology, a mainstay in solar panel manufacturing, faces competition from emerging alternatives. Solar powered refrigeration systems are revolutionizing cold storage solutions, while solar tracking systems optimize panel efficiency. Commercial solar adoption is on the rise, with businesses recognizing the cost savings and sustainability benefits. Solar panel warranty and performance degradation are key considerations for investors and consumers alike. Solar panel manufacturing processes are continuously improving, with a focus on reducing costs and increasing efficiency. Solar energy storage and solar energy policy are crucial components of the renewable energy landscape. Industrial solar applications are expanding, from powering factories to providing clean energy for heavy industry. Solar panel maintenance and cleaning are essential for maximizing system performance and longevity. Battery energy storage and net metering are transforming the way we store and distribute solar energy. Solar farm development and ground-mounted solar installations are shaping the future of utility-scale solar. Solar powered electronics, from calculators to smartphones, are becoming increasingly common. Solar powered homes and solar powered buildings are the future of sustainable living. The market is a dynamic and evolving landscape, with endless possibilities.

How is this Solar Panels Industry segmented?

The solar panels industry research report provides comprehensive data (region-wise segment analysis), with forecasts and estimates in 'USD billion' for the period 2025-2029, as well as historical data from 2019-2023 for the following segments. End-userPower utilitiesCommercialResidentialTypeCrystalline panelThin-film panelConnectivityOn-gridOff-gridTechnologySolar PVConcentrated solar power (CSP)GeographyNorth AmericaUSCanadaEuropeFranceGermanyItalyUKAPACChinaIndiaJapanSouth KoreaRest of World (ROW).

By End-user Insights

The power utilities segment is estimated to witness significant growth during the forecast period.The solar panel market experienced significant growth in 2024, with the power utility segment leading the way. Utility-scale solar power plants continued to expand, contributing to the reduction of carbon emissions and the generation of clean energy. According to the International Energy Agency (IEA), renewable capacity additions reached record levels in 2024, with solar photovoltaics (PV) accounting for around 80% of the growth in renewable electricity capacity. China, the US, Germany, Japan, and India were among the major contributors to the utility segment. For instance, China installed 277 GW of solar capacity in 2024, as reported by the National Energy Administration (NEA). Residential solar installations also gained traction, with homeowners seeking to save on energy costs and reduce their carbon footprint. Solar panel financing options, such as leasing and power purchase agreements, made solar adoption more accessible. Solar panel costs continued to decline, making solar energy a cost-effective solution for both

The National Renewable Energy Laboratory's (NREL) Photovoltaic (PV) Rooftop Database (PVRDB) is a lidar-derived, geospatially-resolved dataset of suitable roof surfaces and their PV technical potential for 128 metropolitan regions in the United States. The PVRDB data are organized by city and year of lidar collection. Five geospatial layers are available for each city and year: 1) the raster extent of the lidar collection, 2) buildings identified from the lidar data, 3) suitable developable planes for each building, 4) aspect values of the developable planes, and 5) the technical potential estimates of the developable planes.

Solar energy accounted for roughly *** percent of electricity generation worldwide in 2023, up from a *** percent share a year earlier. That year, wind and solar generated nearly ** percent of global electricity.

Increase the amount of solar energy generated by increasing the number of solar panels.

This dataset includes information on completed and pipeline (not yet installed) solar electric projects supported by the New York State Energy Research and Development Authority (NYSERDA). Blank cells represent data that were not required or are not currently available. Contractor data is provided for completed projects only, except for Community Distributed Generation projects. Pipeline projects are subject to change. The interactive map at https://data.ny.gov/Energy-Environment/Solar-Electric-Programs-Reported-by-NYSERDA-Beginn/3x8r-34rs provides information on solar photovoltaic (PV) installations supported by NYSERDA throughout New York State since 2000 by county, region, or statewide. Updated monthly, the graphs show the number of projects, expected production, total capacity, and annual trends.

The New York State Energy Research and Development Authority (NYSERDA) offers objective information and analysis, innovative programs, technical expertise, and support to help New Yorkers increase energy efficiency, save money, use renewable energy, and reduce reliance on fossil fuels. To learn more about NYSERDA’s programs, visit https://nyserda.ny.gov or follow us on X, Facebook, YouTube, or Instagram.

On-Site Photovoltaic Solar Power for Data Centers Market Outlook

The on-site photovoltaic solar power for data centers market size was valued at approximately USD 1.5 billion in 2023 and is projected to reach around USD 4.5 billion by 2032, exhibiting a compound annual growth rate (CAGR) of 12.5%. The growth in this market is primarily driven by the increasing demand for renewable energy sources, stringent government regulations regarding carbon emissions, and the rapid expansion of data centers globally.

One of the key growth factors in this market is the rising awareness and adoption of renewable energy sources among data center operators. As the world becomes more conscious of its carbon footprint, companies are seeking sustainable ways to power their data centers. Solar energy, being a clean and abundant resource, is becoming a preferred choice. The increasing demand for data storage and processing capabilities, driven by the exponential growth in internet usage, big data analytics, and the proliferation of IoT devices, is pushing data centers to seek more efficient and sustainable energy solutions.

Another significant factor contributing to market growth is the advancement in photovoltaic technology. Innovations in solar panel efficiency and reductions in the cost of solar photovoltaic systems are making it more economically viable for data centers to install on-site solar power systems. Enhanced inverter technologies and the integration of sophisticated monitoring and control systems are further boosting the efficiency and reliability of these solar power installations. As a result, data center operators are increasingly investing in these technologies to reduce their operational costs and enhance energy independence.

Government policies and incentives are also playing a crucial role in promoting the use of solar power in data centers. Various governments around the world are offering tax benefits, subsidies, and grants to encourage the adoption of renewable energy. Stringent regulations regarding carbon emissions and energy efficiency standards are compelling data center operators to explore green energy alternatives. The supportive regulatory framework is expected to continue driving the adoption of on-site photovoltaic solar power in the data center industry over the forecast period.

Regionally, North America is currently the largest market for on-site photovoltaic solar power in data centers, followed by Europe and Asia Pacific. The presence of a large number of data centers and favorable government policies in the United States and Canada are major factors contributing to North America's market dominance. In Europe, stringent environmental regulations and significant investments in renewable energy infrastructure are driving the market. Asia Pacific is expected to witness the highest growth rate during the forecast period, driven by the rapid expansion of data centers in countries like China, India, and Japan, coupled with increasing government support for renewable energy adoption.

Component Analysis

The component segment of the on-site photovoltaic solar power for data centers market includes solar panels, inverters, mounting systems, monitoring and control systems, and others. Solar panels are the primary component, capturing sunlight and converting it into electrical energy. The efficiency and quality of solar panels significantly impact the overall performance of the solar power system. Advances in photovoltaic cell technology, such as the development of bifacial panels and PERC (Passivated Emitter and Rear Cell) technology, are enhancing the efficiency and output of solar panels, making them more attractive for data center applications.

Inverters are another critical component in the solar power system, converting the direct current (DC) generated by the solar panels into alternating current (AC), which is used by data center equipment. The reliability and efficiency of inverters are crucial for maintaining a consistent power supply. Innovations in inverter technology, such as the development of string inverters and central inverters with advanced features like maximum power point tracking (MPPT), are improving the performance of solar power systems in data centers.

Mounting systems play a vital role in the installation and stability of solar panels. These systems must be designed to withstand various environmental conditions while maximizing the exposure of solar panels to sunlight. The choice of mounting system depends on factors such as roof type, tilt angle, and wind load requirements. Advanced mo

This dataset contains over two years of 1-minute resolution data collected from four floating solar sites, as well as data from a land-based PV system co-located with one of the floating sites. The dataset includes highly granular module temperature measurements - five modules per floating site, with three sensors per module, totaling 15 module temperature sensors per floating site. In addition to the module temperature data, meteorological data collected at the floating sites is also included, along with traditional PV system-level parameters. The data is intended for analysis of solar energy production, efficiency, and performance degradation over time. For information about the data file usage see the "README" resource below. See "Metadata File" for information about individual files and other metadata information.

The Report Covers On-Site Photovoltaic Solar Power for Data Centers Market Size & Share and It is Segmented by Geography (North America, Europe, Asia-pacific, South America, And Middle-East and Africa). The Report Offers the Market Size and Forecasts for On-Site Photovoltaic Solar Power for Data Centers in Revenue (USD) for all the Above Segments.

Earth-observing remote sensing data, including aerial photography and satellite imagery, offer a snapshot of the world from which we can learn about the state of our environment, anthropogenic systems, and natural resources. The components of energy systems that are visible from above may be assessed with these remote sensing data when combined with machine learning methods. Here we focus on the information gap in distributed solar photovoltaic (PV) arrays, of which there is limited data on solar PV deployments at small geographic scales. We created a machine learning dataset to develop the process of automatically identifying solar PV locations through the use of remote sensing imagery.This dataset contains the geospatial coordinates and border vertices for 19,433 solar panels across 601 high resolution images from four cities in California. Dataset applications include training object detection and other machine learning algorithms that use remote sensing imagery, developing specific algorithms for predictive detection of distributed PV systems, and analysis of the socioeconomic correlates of PV deployment.Links to the aerial photographs from Fresno, Stockton, Oxnard, and Modesto can be found in the references.Notes: this version of the dataset has been improved to increase the accuracy of polygon georeferencing so that the data can be more easily integrated with imagery other than than the original imagery from which the annotations were based. Additionally, a small number of polygons were found to be erroneous annotations and either corrected or removed.Update July 30, 2020: Panel area in pixels and area in square meters were labeled incorrectly in the original version; those labels were reversed. Updated files include: 'polygonDataExceptVertices.csv', 'SolarArrayPolygons.geojson', 'SolarArrayPolygons.json'.

Subscribers can find out export and import data of 23 countries by HS code or product’s name. This demo is helpful for market analysis.

In 2023, Indonesia's solar energy capacity was approximately 574 megawatts, showing a sharp increase from the year prior. At the end of 2020, Indonesia officially started the development of Cirata floating solar power plant in West Java, which has now become Indonesia's largest solar power plant and Southeast Asia's largest floating power plant.

China Electricity Production: Solar Photovoltaic data was reported at 427.300 kWh bn in 2022. This records an increase from the previous number of 325.700 kWh bn for 2021. China Electricity Production: Solar Photovoltaic data is updated yearly, averaging 147.350 kWh bn from Dec 2013 (Median) to 2022, with 10 observations. The data reached an all-time high of 427.300 kWh bn in 2022 and a record low of 8.374 kWh bn in 2013. China Electricity Production: Solar Photovoltaic data remains active status in CEIC and is reported by National Bureau of Statistics. The data is categorized under China Premium Database’s Energy Sector – Table CN.RBA: Energy Production: Electricity: Solar.

The Global Solar Energy Market Size Was Worth $90.4 Billion in 2022 and Is Expected To Reach $215.9 Billion by 2030, CAGR of 11.5%.

The market is expected to 10 expand from USD 26,941.5 million in 2025 to USD 49,631.2 million by 2035, at a 11 CAGR of 6.3% over the forecast period. As edge computing continues to skyrocket and AI-driven workloads proliferate, energy efficiency and power autonomy have become increasingly vital touchpoints for the next generation of data centers. In response, operators are looking more and more to on-site solar systems commonly with battery storage that lock in stable energy costs and maximize grid independence, uptime.

Metric	Value
Market Size (2025E)	USD 26,941.5 million
Market Value (2035F)	USD 49,631.2 million
CAGR (2025 to 2035)	6.3%

Country-wise Insights

Country	CAGR (2025 to 2035)
United States	6.6%

Country	CAGR (2025 to 2035)
United Kingdom	6.0%

Region	CAGR (2025 to 2035)
Europe	6.2%

Country	CAGR (2025 to 2035)
Japan	6.4%

Country	CAGR (2025 to 2035)
South Korea	6.5%

Segmentation Outlook - On-Site Photovoltaic Solar Power for Data Centers Market

Sub-Segment	Market Share (2025)
Monocrystalline Silicon Photovoltaic Panels	53.2%

Sub-Segment	Market Share (2025)
On-Grid Connected	61.5%

Competitive Outlook

Company Name	Estimated Market Share (%)
Trina Solar	17-20%
JA Solar Co., Ltd.	15-18%
SunPower Corporation	12-15%
Jinko Solar	9-12%
Canadian Solar	8-10%
Other Companies (combined)	25-30%