1 Market Overview

• 1.1 Product Overview and Scope
• 1.2 Market Estimation Caveats and Base Year
• 1.3 Market Analysis by Type
  • 1.3.1 Overview: Global Solar Thermal (CSP) Consumption Value by Type: 2021 Versus 2025 Versus 2032
  • 1.3.2 Power Tower
  • 1.3.3 Parabolic Trough
  • 1.3.4 Linear Fresnel
  • 1.3.5 Dish
• 1.4 Market Analysis by Generation Capacity
  • 1.4.1 Overview: Global Solar Thermal (CSP) Consumption Value by Generation Capacity: 2021 Versus 2025 Versus 2032
  • 1.4.2 Less than 10MW
  • 1.4.3 10-100MW
  • 1.4.4 More than 100MW
• 1.5 Market Analysis by Usage Scenarios
  • 1.5.1 Overview: Global Solar Thermal (CSP) Consumption Value by Usage Scenarios: 2021 Versus 2025 Versus 2032
  • 1.5.2 Grid-Connected Dispatchable Power
  • 1.5.3 Capacity and Ancillary Services
  • 1.5.4 Others
• 1.6 Market Analysis by Application
  • 1.6.1 Overview: Global Solar Thermal (CSP) Consumption Value by Application: 2021 Versus 2025 Versus 2032
  • 1.6.2 Heat Generation
  • 1.6.3 Power Generation
• 1.7 Global Solar Thermal (CSP) Market Size & Forecast
  • 1.7.1 Global Solar Thermal (CSP) Consumption Value (2021 & 2025 & 2032)
  • 1.7.2 Global Solar Thermal (CSP) Sales Quantity (2021-2032)
  • 1.7.3 Global Solar Thermal (CSP) Average Price (2021-2032)

2 Manufacturers Profiles

• 2.1 Abengoa
  • 2.1.1 Abengoa Details
  • 2.1.2 Abengoa Major Business
  • 2.1.3 Abengoa Solar Thermal (CSP) Product and Services
  • 2.1.4 Abengoa Solar Thermal (CSP) Sales Quantity, Average Price, Revenue, Gross Margin and Market Share (2021-2026)
  • 2.1.5 Abengoa Recent Developments/Updates
• 2.2 Bosch Thermotechnology
  • 2.2.1 Bosch Thermotechnology Details
  • 2.2.2 Bosch Thermotechnology Major Business
  • 2.2.3 Bosch Thermotechnology Solar Thermal (CSP) Product and Services
  • 2.2.4 Bosch Thermotechnology Solar Thermal (CSP) Sales Quantity, Average Price, Revenue, Gross Margin and Market Share (2021-2026)
  • 2.2.5 Bosch Thermotechnology Recent Developments/Updates
• 2.3 ACCIONA
  • 2.3.1 ACCIONA Details
  • 2.3.2 ACCIONA Major Business
  • 2.3.3 ACCIONA Solar Thermal (CSP) Product and Services
  • 2.3.4 ACCIONA Solar Thermal (CSP) Sales Quantity, Average Price, Revenue, Gross Margin and Market Share (2021-2026)
  • 2.3.5 ACCIONA Recent Developments/Updates
• 2.4 GREENoneTEC
  • 2.4.1 GREENoneTEC Details
  • 2.4.2 GREENoneTEC Major Business
  • 2.4.3 GREENoneTEC Solar Thermal (CSP) Product and Services
  • 2.4.4 GREENoneTEC Solar Thermal (CSP) Sales Quantity, Average Price, Revenue, Gross Margin and Market Share (2021-2026)
  • 2.4.5 GREENoneTEC Recent Developments/Updates
• 2.5 Viessmann
  • 2.5.1 Viessmann Details
  • 2.5.2 Viessmann Major Business
  • 2.5.3 Viessmann Solar Thermal (CSP) Product and Services
  • 2.5.4 Viessmann Solar Thermal (CSP) Sales Quantity, Average Price, Revenue, Gross Margin and Market Share (2021-2026)
  • 2.5.5 Viessmann Recent Developments/Updates

3 Competitive Environment: Solar Thermal (CSP) by Manufacturer

• 3.1 Global Solar Thermal (CSP) Sales Quantity by Manufacturer (2021-2026)
• 3.2 Global Solar Thermal (CSP) Revenue by Manufacturer (2021-2026)
• 3.3 Global Solar Thermal (CSP) Average Price by Manufacturer (2021-2026)
• 3.4 Market Share Analysis (2025)
  • 3.4.1 Producer Shipments of Solar Thermal (CSP) by Manufacturer Revenue ($MM) and Market Share (%): 2025
  • 3.4.2 Top 3 Solar Thermal (CSP) Manufacturer Market Share in 2025
  • 3.4.3 Top 6 Solar Thermal (CSP) Manufacturer Market Share in 2025
• 3.5 Solar Thermal (CSP) Market: Overall Company Footprint Analysis
  • 3.5.1 Solar Thermal (CSP) Market: Region Footprint
  • 3.5.2 Solar Thermal (CSP) Market: Company Product Type Footprint
  • 3.5.3 Solar Thermal (CSP) Market: Company Product Application Footprint
• 3.6 New Market Entrants and Barriers to Market Entry
• 3.7 Mergers, Acquisition, Agreements, and Collaborations

4 Consumption Analysis by Region

• 4.1 Global Solar Thermal (CSP) Market Size by Region
  • 4.1.1 Global Solar Thermal (CSP) Sales Quantity by Region (2021-2032)
  • 4.1.2 Global Solar Thermal (CSP) Consumption Value by Region (2021-2032)
  • 4.1.3 Global Solar Thermal (CSP) Average Price by Region (2021-2032)
• 4.2 North America Solar Thermal (CSP) Consumption Value (2021-2032)
• 4.3 Europe Solar Thermal (CSP) Consumption Value (2021-2032)
• 4.4 Asia-Pacific Solar Thermal (CSP) Consumption Value (2021-2032)
• 4.5 South America Solar Thermal (CSP) Consumption Value (2021-2032)
• 4.6 Middle East & Africa Solar Thermal (CSP) Consumption Value (2021-2032)

5 Market Segment by Type

• 5.1 Global Solar Thermal (CSP) Sales Quantity by Type (2021-2032)
• 5.2 Global Solar Thermal (CSP) Consumption Value by Type (2021-2032)
• 5.3 Global Solar Thermal (CSP) Average Price by Type (2021-2032)

6 Market Segment by Application

• 6.1 Global Solar Thermal (CSP) Sales Quantity by Application (2021-2032)
• 6.2 Global Solar Thermal (CSP) Consumption Value by Application (2021-2032)
• 6.3 Global Solar Thermal (CSP) Average Price by Application (2021-2032)

7 North America

• 7.1 North America Solar Thermal (CSP) Sales Quantity by Type (2021-2032)
• 7.2 North America Solar Thermal (CSP) Sales Quantity by Application (2021-2032)
• 7.3 North America Solar Thermal (CSP) Market Size by Country
  • 7.3.1 North America Solar Thermal (CSP) Sales Quantity by Country (2021-2032)
  • 7.3.2 North America Solar Thermal (CSP) Consumption Value by Country (2021-2032)
  • 7.3.3 United States Market Size and Forecast (2021-2032)
  • 7.3.4 Canada Market Size and Forecast (2021-2032)
  • 7.3.5 Mexico Market Size and Forecast (2021-2032)

8 Europe

• 8.1 Europe Solar Thermal (CSP) Sales Quantity by Type (2021-2032)
• 8.2 Europe Solar Thermal (CSP) Sales Quantity by Application (2021-2032)
• 8.3 Europe Solar Thermal (CSP) Market Size by Country
  • 8.3.1 Europe Solar Thermal (CSP) Sales Quantity by Country (2021-2032)
  • 8.3.2 Europe Solar Thermal (CSP) Consumption Value by Country (2021-2032)
  • 8.3.3 Germany Market Size and Forecast (2021-2032)
  • 8.3.4 France Market Size and Forecast (2021-2032)
  • 8.3.5 United Kingdom Market Size and Forecast (2021-2032)
  • 8.3.6 Russia Market Size and Forecast (2021-2032)
  • 8.3.7 Italy Market Size and Forecast (2021-2032)

9 Asia-Pacific

• 9.1 Asia-Pacific Solar Thermal (CSP) Sales Quantity by Type (2021-2032)
• 9.2 Asia-Pacific Solar Thermal (CSP) Sales Quantity by Application (2021-2032)
• 9.3 Asia-Pacific Solar Thermal (CSP) Market Size by Region
  • 9.3.1 Asia-Pacific Solar Thermal (CSP) Sales Quantity by Region (2021-2032)
  • 9.3.2 Asia-Pacific Solar Thermal (CSP) Consumption Value by Region (2021-2032)
  • 9.3.3 China Market Size and Forecast (2021-2032)
  • 9.3.4 Japan Market Size and Forecast (2021-2032)
  • 9.3.5 South Korea Market Size and Forecast (2021-2032)
  • 9.3.6 India Market Size and Forecast (2021-2032)
  • 9.3.7 Southeast Asia Market Size and Forecast (2021-2032)
  • 9.3.8 Australia Market Size and Forecast (2021-2032)

10 South America

• 10.1 South America Solar Thermal (CSP) Sales Quantity by Type (2021-2032)
• 10.2 South America Solar Thermal (CSP) Sales Quantity by Application (2021-2032)
• 10.3 South America Solar Thermal (CSP) Market Size by Country
  • 10.3.1 South America Solar Thermal (CSP) Sales Quantity by Country (2021-2032)
  • 10.3.2 South America Solar Thermal (CSP) Consumption Value by Country (2021-2032)
  • 10.3.3 Brazil Market Size and Forecast (2021-2032)
  • 10.3.4 Argentina Market Size and Forecast (2021-2032)

11 Middle East & Africa

• 11.1 Middle East & Africa Solar Thermal (CSP) Sales Quantity by Type (2021-2032)
• 11.2 Middle East & Africa Solar Thermal (CSP) Sales Quantity by Application (2021-2032)
• 11.3 Middle East & Africa Solar Thermal (CSP) Market Size by Country
  • 11.3.1 Middle East & Africa Solar Thermal (CSP) Sales Quantity by Country (2021-2032)
  • 11.3.2 Middle East & Africa Solar Thermal (CSP) Consumption Value by Country (2021-2032)
  • 11.3.3 Turkey Market Size and Forecast (2021-2032)
  • 11.3.4 Egypt Market Size and Forecast (2021-2032)
  • 11.3.5 Saudi Arabia Market Size and Forecast (2021-2032)
  • 11.3.6 South Africa Market Size and Forecast (2021-2032)

12 Market Dynamics

• 12.1 Solar Thermal (CSP) Market Drivers
• 12.2 Solar Thermal (CSP) Market Restraints
• 12.3 Solar Thermal (CSP) Trends Analysis
• 12.4 Porters Five Forces Analysis
  • 12.4.1 Threat of New Entrants
  • 12.4.2 Bargaining Power of Suppliers
  • 12.4.3 Bargaining Power of Buyers
  • 12.4.4 Threat of Substitutes
  • 12.4.5 Competitive Rivalry

13 Raw Material and Industry Chain

• 13.1 Raw Material of Solar Thermal (CSP) and Key Manufacturers
• 13.2 Manufacturing Costs Percentage of Solar Thermal (CSP)
• 13.3 Solar Thermal (CSP) Production Process
• 13.4 Industry Value Chain Analysis

14 Shipments by Distribution Channel

• 14.1 Sales Channel
  • 14.1.1 Direct to End-User
  • 14.1.2 Distributors
• 14.2 Solar Thermal (CSP) Typical Distributors
• 14.3 Solar Thermal (CSP) Typical Customers

15 Research Findings and Conclusion

16 Appendix

• 16.1 Methodology
• 16.2 Research Process and Data Source

According to our (Global Info Research) latest study, the global Solar Thermal (CSP) market size was valued at US$ 2605 million in 2025 and is forecast to a readjusted size of US$ 11689 million by 2032 with a CAGR of 21.2% during review period.
Solar Thermal (Concentrated Solar Power, “CSP”) in this report is defined as a capital-intensive system solution rather than a commodity fuel or a stream of electricity sales. CSP plants use mirrors to concentrate sunlight onto a receiver, convert it into high-temperature heat, and then deliver this heat to a conventional power block or industrial process. Combined with thermal energy storage (TES), CSP can decouple solar collection from final energy use and provide firm, dispatchable heat and power that complements variable renewables such as PV and wind.
From a technology perspective, the industry is organised around four main system archetypes: Power Tower, Parabolic Trough, Linear Fresnel, and Parabolic Dish. These configurations differ in optical layout, receiver concept, heat-transfer fluid and storage design, but they are all engineered and delivered as integrated “plant packages” that include the solar field, receiver and piping, storage system, and power block and/or process-heat island. In practice, the global market is dominated by large, utility-scale tower and trough plants, often hybridised with PV, gas or other assets; Fresnel and dish solutions are more niche and typically address specific site or process-heat opportunities.
Commercially, CSP is a project-based EPC market. Projects are developed by utilities, IPPs, state-owned entities or industrial users, and then tendered as multi-year EPC, EPCM or turnkey contracts. A limited group of experienced integrators and engineering contractors (including diversified construction groups and specialised CSP players) compete to design and deliver the CSP “island” and, in many cases, the wider balance of plant. Revenue for CSP vendors is therefore recognised primarily at contract award and during construction, not as ongoing payments for electricity or heat. Long-term cash flows from power purchase agreements (PPAs), capacity payments or industrial heat offtake are fundamental to project bankability, but they accrue mainly to developers and asset owners, not to EPC contractors.
1. Positioning of Solar Thermal & CPV/CPVT in a PV-dominated world
The evidence assembled in this report confirms that Solar Thermal (CSP) and Concentrated Photovoltaic / Photovoltaic-Thermal (CPV/CPVT) technologies remain niche in terms of installed capacity, but strategically important in terms of system value. By 2023, global CSP capacity was only around 8 GW – less than 1% of total solar capacity – compared with well above 2 TW of installed solar PV by 2024.
Against this backdrop, the project universe and market sizing work in this study highlight two core points:
1.1 Scale gap vs. PV is structural, not temporary. CSP and CPV/CPVT will not close the volume gap with commodity PV modules; instead, they compete on dispatchability, high-temperature heat and co-generation value, not on installed megawatts alone.
1.2 System-value lens is decisive. Wherever tariffs and market design remunerate firm low-carbon capacity and long-duration flexibility, Solar Thermal and hybrid CPV/CPVT solutions become relevant options despite higher specific CAPEX. Where these attributes are not priced, project pipelines stall even under strong resource conditions.
In our view, this asymmetry explains why CSP/CPVT deployment remains geographically concentrated while medium- and long-term scenarios (IEA, IRENA) still assume a several-fold increase in CSP capacity by 2030 (typically 50–80 GW vs. ~8 GW today).
2. Growth will be policy-led and geographically concentrated
The project database underpinning this report shows that future Solar Thermal growth is anchored in a small set of policy-driven markets rather than broad, organic global adoption:
2.1 China already accounts for a material share of global CSP additions and is now the single most important growth market. By mid-2025, China had around 1.1 GW of operational CSP and a pipeline exceeding 8 GW across Qinghai, Gansu, Inner Mongolia and Xinjiang. A late-2025 official document sets an indicative target of around 15 GW of CSP capacity in the next planning period, explicitly positioning solar thermal as part of desert-base mega-projects and as a dispatchable resource in high-renewables systems.
2.2 MENA and selected emerging markets (e.g. Morocco, UAE, Saudi Arabia, parts of Southern Africa and Latin America) continue to develop large individual plants and hybrid complexes. Flagship projects like the 700 MW CSP + 250 MW PV Noor Energy 1 / DEWA IV complex in Dubai, with 12–15 hours of molten-salt storage, illustrate how CSP is used to deliver round-the-clock solar power into evening peaks.
2.3 Other regions – Europe, North America, OECD Asia – are present mainly through legacy plants, R&D activities and a small number of niche or repowering projects. In these markets, high wholesale price volatility, uncertain long-term support frameworks and strong competition from PV plus batteries limit new CSP/CPVT investment to very specific applications.
Our assessment is that this concentration is unlikely to change materially over the next decade. The national-level policy frameworks and auction designs reviewed in the report suggest that:
2.4 Most incremental CSP capacity through 2030 will come from China and MENA;
2.5 Other markets will contribute opportunistically, often via single landmark projects rather than continuous pipelines;
2.6 For CPVT in particular, industrial heat and co-generation rather than grid-only power will be the main driver.
3. Technology mix: from trough legacy to tower, hybrids and CPVT
The historical base in our project universe remains dominated by parabolic trough plants, reflecting the first two commercialisation waves of CSP. This is consistent with global statistics, where trough technology still accounts for the majority of the ~6–7 GW operational fleet. However, the forward-looking pipeline and scenario work in this report indicate a clear technological pivot:
3.1 Molten-salt tower as the new reference. In China’s recent batches, in Gulf mega-projects and in several industrial-heat designs, molten-salt power towers increasingly serve as the default reference case, supported by higher operating temperatures, more compact layouts and improved storage integration. This is aligned with external assessments that see the strongest cost-reduction potential in tower configurations.
3.2 Hybridisation as de-risking tool. Projects such as DEWA IV (trough + tower + PV) and emerging Chinese “CSP+PV+wind” bases show that sponsors now routinely combine multiple technologies within a single complex to diversify construction risk and optimise the output profile. Our project-level analysis confirms that most recently announced plants include some form of hybrid component (PV and/or conventional generation), with pure-play stand-alone CSP becoming less common.
3.3 CPV/CPVT moving from concept to pilot, not yet to scale. On the CPV/CPVT side, the technical literature documents impressive laboratory and pilot-scale performance: multi-junction CPV cells have reached efficiencies close to 48%, while recent CPVT system reviews report combined electrical-thermal efficiencies in the 60–80% range and LCoE estimates competitive with other renewables in high-DNI sites. Yet the project mapping in this study finds that real-world deployment remains limited to small pilot plants, building-scale demonstrators and a handful of industrial-heat projects, with no CPVT plant currently approaching the scale of mainstream CSP utility projects.
Our conclusion is that, within the study horizon, molten-salt tower CSP with integrated storage is the workhorse utility-scale option, while CPV/CPVT is best viewed as an emerging technology family with credible technical potential but still lacking the bankable, multi-plant track record required for broad adoption.
4. Economics: premium CAPEX, but competitive in long-duration flexibility niches
The cost evidence assembled in the report, cross-checked against international benchmarks, points to a persistent but narrowing cost gap between Solar Thermal solutions and alternative low-carbon options:
4.1 Recent cost surveys show that new CSP additions remain more capital-intensive than PV and onshore wind, and that annual CSP capacity additions have been relatively flat in recent years despite record growth in overall renewables.
4.2 However, headline CAPEX is a poor proxy for system value. In high-DNI sites with 8–15 hours of storage, CSP plants can deliver firm, dispatchable output that directly competes with gas-fired peakers or PV plus long-duration storage. Flagship projects in Dubai and elsewhere have already set PPA prices in the mid-single-digit US cents per kWh despite long storage durations, supported by concessional finance and scale efficiencies.
4.3 For CPVT, techno-economic studies indicate that, at favourable sites and with optimised designs, combined electricity-and-heat output can achieve LCoE estimates broadly similar to other renewables, particularly where high-temperature process heat has high marginal value; yet these numbers remain largely model-based and require validation through real assets.
Our interpretation is that economics are highly context-specific:
4.4 In systems that do not explicitly reward flexibility or high-temperature heat, CSP/CPVT will struggle to compete with PV plus batteries.
4.5 In systems where evening peaks, firm capacity needs and industrial decarbonisation are binding constraints, the premium CAPEX of CSP/CPVT is justifiable and, in some cases, economically attractive.
This asymmetry underpins our base-case forecast: limited global volumes but economically rational growth in a series of well-defined niches.
5. Competitive dynamics: from European pioneers to China-anchored industrialisation
The company-level mapping in this report shows a market structure characterised by:
5.1 A small group of globally active EPC and technology players (many with European or Middle Eastern origins) that provide reference plants, key components and know-how;
5.2 Rapidly rising participation by Chinese EPCs and manufacturers, leveraging experience from domestic demonstration batches and large desert-base projects, as well as integrated supply chains spanning mirrors, receivers, molten-salt equipment and control systems;
5.3 A long tail of local civil-works contractors, peripheral component suppliers and specialised service firms, often tied to a single project or region.
Over the forecast period, we expect competitive advantage to be determined less by proprietary hardware and more by:
5.4 Bankable reference portfolios – demonstrated ability to deliver CSP/CPVT plants on time, on budget and at or above guaranteed performance;
5.5 Standardised yet flexible plant architectures – re-use of proven “platforms” (e.g. 100 MW tower blocks with fixed storage hours) that can be replicated across markets, while allowing local adaptation;
5.6 System-integration and lifecycle capabilities – combining solar field, storage, power block, digital control and O&M into integrated offerings, particularly for complex hybrid projects (CSP+PV+wind+storage).
In this landscape, we see a gradual shift of manufacturing and EPC cost leadership toward China, while technology origination and complex system design remains more distributed, with long-standing European and other players still important in high-specification or first-of-a-kind projects.
6. Implications and watchpoints
Synthesising the quantitative and qualitative findings of this study, our main conclusions are:
6.1 Solar Thermal and CPV/CPVT are moving from “experimental” to “strategic niche” status. The current fleet is small, but selected markets are clearly internalising their system value. This justifies continued tracking and dedicated allocation of development effort within diversified renewable portfolios.
6.2 Policy clarity on flexibility remuneration is the single most important external driver. Where auctions, capacity markets or regulated tariffs recognise long-duration storage and high-temperature heat, we expect CSP/CPVT pipelines to materialise; where they do not, pipelines will remain sporadic regardless of resource quality.
6.3 China and MENA will define the global learning curve. Their project pipelines, cost trajectories and industrial strategies will set the reference points for technology risk perception and financing conditions worldwide. Monitoring Chinese policy implementation around the 15 GW CSP ambition and the performance of the newest desert-base hybrids is therefore critical for any global outlook.
6.4 For investors, selectivity and structuring matter more than volume. The opportunity set is not about building large portfolios of “plain vanilla” plants, but about a limited number of well-structured, policy-anchored projects with robust offtake, strong sponsors and proven EPC partners.
6.5 For technology developers, CPVT is a high-potential but long-cycle option. The combined-efficiency and high-temperature advantages documented in recent literature are compelling, but commercial relevance depends on successfully bridging the bankability gap – via pilots in industrial clusters, district heating and high-value process-heat applications rather than immediate pursuit of large stand-alone power plants.
Overall, we view Solar Thermal and CPV/CPVT not as broad substitutes for PV and wind, but as complementary, high-value tools in a decarbonisation toolbox that must increasingly deliver flexibility, firm capacity and high-temperature heat alongside low-cost energy. The project universe, cost benchmarks and forward-looking scenarios in this report support a measured but positive outlook for these technologies within the clearly defined boundaries described above.
This report is a detailed and comprehensive analysis for global Solar Thermal (CSP) market. Both quantitative and qualitative analyses are presented by manufacturers, by region & country, by Type and by Application. As the market is constantly changing, this report explores the competition, supply and demand trends, as well as key factors that contribute to its changing demands across many markets. Company profiles and product examples of selected competitors, along with market share estimates of some of the selected leaders for the year 2025, are provided.
Key Features:
Global Solar Thermal (CSP) market size and forecasts, in consumption value ($ Million), sales quantity (KW), and average selling prices (USD/KW), 2021-2032
Global Solar Thermal (CSP) market size and forecasts by region and country, in consumption value ($ Million), sales quantity (KW), and average selling prices (USD/KW), 2021-2032
Global Solar Thermal (CSP) market size and forecasts, by Type and by Application, in consumption value ($ Million), sales quantity (KW), and average selling prices (USD/KW), 2021-2032
Global Solar Thermal (CSP) market shares of main players, shipments in revenue ($ Million), sales quantity (KW), and ASP (USD/KW), 2021-2026
The Primary Objectives in This Report Are:
To determine the size of the total market opportunity of global and key countries
To assess the growth potential for Solar Thermal (CSP)
To forecast future growth in each product and end-use market
To assess competitive factors affecting the marketplace
This report profiles key players in the global Solar Thermal (CSP) market based on the following parameters - company overview, sales quantity, revenue, price, gross margin, product portfolio, geographical presence, and key developments. Key companies covered as a part of this study include Abengoa, Bosch Thermotechnology, ACCIONA, GREENoneTEC, Viessmann, etc.
This report also provides key insights about market drivers, restraints, opportunities, new product launches or approvals.
Market Segmentation
Solar Thermal (CSP) market is split by Type and by Application. For the period 2021-2032, the growth among segments provides accurate calculations and forecasts for consumption value by Type, and by Application in terms of volume and value. This analysis can help you expand your business by targeting qualified niche markets.
Market segment by Type
Power Tower
Parabolic Trough
Linear Fresnel
Dish
Market segment by Generation Capacity
Less than 10MW
10-100MW
More than 100MW
Market segment by Usage Scenarios
Grid-Connected Dispatchable Power
Capacity and Ancillary Services
Others
Market segment by Application
Heat Generation
Power Generation
Major players covered
Abengoa
Bosch Thermotechnology
ACCIONA
GREENoneTEC
Viessmann
Market segment by region, regional analysis covers
North America (United States, Canada, and Mexico)
Europe (Germany, France, United Kingdom, Russia, Italy, and Rest of Europe)
Asia-Pacific (China, Japan, Korea, India, Southeast Asia, and Australia)
South America (Brazil, Argentina, Colombia, and Rest of South America)
Middle East & Africa (Saudi Arabia, UAE, Egypt, South Africa, and Rest of Middle East & Africa)
The content of the study subjects, includes a total of 15 chapters:
Chapter 1, to describe Solar Thermal (CSP) product scope, market overview, market estimation caveats and base year.
Chapter 2, to profile the top manufacturers of Solar Thermal (CSP), with price, sales quantity, revenue, and global market share of Solar Thermal (CSP) from 2021 to 2026.
Chapter 3, the Solar Thermal (CSP) competitive situation, sales quantity, revenue, and global market share of top manufacturers are analyzed emphatically by landscape contrast.
Chapter 4, the Solar Thermal (CSP) breakdown data are shown at the regional level, to show the sales quantity, consumption value, and growth by regions, from 2021 to 2032.
Chapter 5 and 6, to segment the sales by Type and by Application, with sales market share and growth rate by Type, by Application, from 2021 to 2032.
Chapter 7, 8, 9, 10 and 11, to break the sales data at the country level, with sales quantity, consumption value, and market share for key countries in the world, from 2021 to 2026.and Solar Thermal (CSP) market forecast, by regions, by Type, and by Application, with sales and revenue, from 2027 to 2032.
Chapter 12, market dynamics, drivers, restraints, trends, and Porters Five Forces analysis.
Chapter 13, the key raw materials and key suppliers, and industry chain of Solar Thermal (CSP).
Chapter 14 and 15, to describe Solar Thermal (CSP) sales channel, distributors, customers, research findings and conclusion.