2025年-2035年薄膜光伏市场:技术、参与者和趋势
按光伏技术和应用领域细分的十年薄膜太阳能市场预测,以及成本分析、主要参与者详评和数据驱动基准测试
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本报告对薄膜光伏市场进行了全方位、深入的分析,不仅涵盖了市场的技术层面、主要参与者,还准确捕捉了行业发展的关键趋势。除了数据驱动的基准测试、应用评估和成本分析外,本报告还对8种主流薄膜太阳能技术进行了深入评估。预测显示,到2035年,薄膜太阳能市场规模将超过110亿美元,而钙钛矿光伏则发挥着关键的增长驱动作用。
本报告为整个薄膜光伏领域提供关键市场情报,涵盖主要薄膜太阳能技术、参与者和应用:
市场全面描述与技术展望
- 对全部薄膜光伏技术进行详细分析和数据驱动型基准测试,包括:
• 染料敏化太阳能电池(DSSC)
• 有机太阳能电池(OPV)
• 钙钛矿光伏
• 碲化镉(CdTe)
• 铜铟镓硒(CIGS)
• 砷化镓(GaAs)
• 非晶硅(a-Si)
• 铜锌锡硫(CZTS)光伏
- 评估各类技术的主要和新兴参与者
- 分析推动薄膜光伏技术应用的关键新兴领域
薄膜光伏技术的关键材料趋势
- 评估薄膜光伏的制造方法,包括主要沉积技术的基准测试
- 审查薄膜光伏的主要材料组件(如基板和封装材料),并分析新兴与成熟技术
新兴串联光伏市场评估
- 覆盖行业关注的核心技术,包括:
• 钙钛矿/硅串联光伏
• 全钙钛矿串联光伏
• 钙钛矿/CIGS串联光伏
- 分析可受益于串联光伏的主要应用领域
市场分析
- 对整个薄膜光伏市场进行详细评估,含35家公司的深度剖析
- 按技术和应用领域划分的2025-2035年薄膜光伏市场预测
- 通过各类技术成本分析,制定未来十年市场收入和组件价格预测
报告主要内容
- 执行摘要与关键结论
- 新兴薄膜光伏技术
• 染料敏化太阳能电池
• 有机太阳能电池
• 钙钛矿光伏
- 无机薄膜光伏技术
• 碲化镉(CdTe)
• 铜铟镓硒(CIGS)
• 砷化镓(GaAs)
• 非晶硅(a-Si)
• 铜锌锡硫(CZTS)
- 串联光伏技术
• 钙钛矿/硅串联
• 全钙钛矿串联
• 其他钙钛矿串联技术
- 主要和新兴薄膜光伏市场参与者
- 薄膜光伏关键材料与制造趋势
- 主要薄膜光伏应用领域
• 太阳能电站
• 住宅屋顶
• 建筑一体化光伏(BIPV)
• 无线电子设备
• 农业光伏
• 汽车应用
- 薄膜光伏市场规模、价值及预测
The renewable energy sector is expanding rapidly, with solar power emerging as one of the fastest-growing technologies. In 2023, global annual investments into solar overtook all other power generation technologies for the first time, including global oil investments. Growth of investment continued into 2024, with the IEA predicting the sector to receive the greatest share of global funding by the end of the year. While silicon photovoltaics (PV) continue to dominate the market, a range of established and emerging technologies have, and continue, to contribute to the sector's evolution. Among them is thin film PV, which has long struggled to compete on the same scale as silicon PV. However, with rising energy demands, ambitious decarbonization targets, and increasing concerns over energy security, could thin film PV uptake be on the rise?
IDTechEx's latest report "Thin Film Photovoltaics Market 2025-2035: Technologies, Technologies, Players & Trends" comprehensively covers the entire thin film PV market. Data driven benchmarking of the established and emerging thin film PV technologies, including dye sensitized solar cells (DSSC), organic solar cells (OPV), perovskite PV, cadmium telluride (CdTe), copper indium gallium selenide (CIGS), gallium arsenide (GaAs), amorphous silicon (a-Si) and copper zinc tin sulfide (CZTS) photovoltaics, along with over 40 profiles of key market payers, helps to outline the entire thin film PV sector. Critical analysis of the major and emerging application areas including solar farms, residential rooftop, building integrated PV, agrivoltaics and wireless electronics, helps to formulate granular 10-year forecasts for the entire solar market. IDTechEx forecasts the thin film PV market to exceed US$11 billion by 2035.
The annual thin film PV installations and market share by technology type.
Thin film solar cells are a sub-class of solar cell, manufactured by the deposition of one or more thin films of photovoltaic material onto a substrate, such as glass, plastic or metal. Aside from the electrodes, each functional layer within a thin-film solar cell generally has a thickness between 5 and 500 nm, enabling an extremely thin power generation device, of typically a few nm to a few microns thick. Thin film PV modules are therefore very lightweight and can be flexible (depending on the substrate choice), meaning they can be installed for low-weight applications, as well as on curved surfaces.
The thin film PV market share has historically remained low, reducing to around 2.5% of all solar market installations as of 2024. Thin film PV technologies have struggled to compete to the same degree as silicon PV, due to their lower performance metrics, raw material concerns, and cost of manufacturing. However, a shift in the technological landscape, along with a broadening of application scope is likely to result in significant changes to the entire thin film market over the next decade.
Novel applications helping to drive market adoption
Thin film PV can be used for traditional solar applications as well as applications where silicon solar technology is not suited. These applications include building integrated PV (BIPV), where the panels are attached to sides of buildings and are incorporated into existing infrastructures. Thin film modules can be up to 90% lighter than silicon modules and therefore are very well suited for vertical building integration, since no significant structural modifications are required. Given the sufficiently greater area of available vertical space compared to rooftop space, this application could contribute significantly to renewable energy initiatives. Some types of thin film PV can also be adjusted in transparency, making them less aesthetically obtrusive and ideally suited for windows.
Other emerging applications belong to the small self-powered electronics and Internet of Things (IoT) sector, which is expected to grow substantially in the coming years as smart electronics become more prevalent in everyday life. These small electronics typically rely on batteries which require replacement every few years at the expense of high material and labor costs. Providing power to these devices using small low-cost PV modules with greater longevity than batteries is a very promising application.
Emerging perovskite PV technology to help drive the thin film market
Perovskite PV has received significant academic and industry attention for its light weight and flexible nature, high manufacturing scalability and significantly lower cost compared to established solar technologies. Perovskite solar cells contain a perovskite active layer which can be deposited as a thin film using solution-based sheet-to-sheet or roll-to-roll compatible processes, making them very attractive from a financial perspective as processing is easily scaled and automated. Along with this, the use of relatively abundant and inexpensive raw materials to synthesize perovskites means that IDTechEx finds perovskite PV to be significantly cheaper than other thin film solar technologies as well as silicon.
As well as fabrication of single junction perovskite solar cells, this technology is also explored for its use in tandem solar cell architectures. All single junction technologies, including established silicon and thin film solar will approach an efficiency plateau. This plateau is expected since there exists a maximum theoretical efficiency limit of 30% for a single junction device. Instead, researchers are exploring the integration of perovskites with other solar technologies in order to achieve much higher power conversion efficiencies. These multi-junction cells possess a much greater theoretical efficiency limit of approximately 43%. The technologies which are receiving significant commercial attention are perovskite/silicon, all-perovskite and perovskite/CIGS tandem PV, with each device posing individual technological advantages.
Perovskite PV has entered early-stage commercialization, with many industry players touting the technology as the "next major solar generation technology". The significant innovation opportunities, rising commercial attention, and consequent predicted growth of the perovskite PV market is a considerable factor helping to revive thin film solar. Current forecasts by IDTechEx, see perovskite PV account for over 40% of all thin film solar installations by 2035.
In this report, IDTechEx further explores the growth drivers for the thin film solar market, as well as analyzing the potential pitfalls to thin film PV adoption. Despite limited market growth thus far, significant ramp up is expected by the end of the decade as the demand for clean and renewable energy continues to grow.
Key Aspects:
Full characterization of the entire thin film photovoltaic market and individual technology outlook
- Detailed analysis and data driven benchmarking of all thin film PV technologies, including dye sensitized solar cells (DSSC), organic solar cells (OPV), perovskite PV, cadmium telluride (CdTe), copper indium gallium selenide (CIGS), gallium arsenide (GaAs), amorphous silicon (a-Si) and copper zinc tin sulfide (CZTS) photovoltaics
- Review of the major and emerging players developing each of the thin film PV technologies
- Analysis of the key and emerging application areas helping to drive the uptake of thin film PV technologies
In depth analysis of the key material trends for thin film photovoltaic technologies
- Assessment of the manufacturing methods for thin film PV, including benchmarking of the major deposition techniques
- Review of the main material components for thin film PV, including substrates and encapsulant materials, along with analysis of the emerging and established technologies
Assessment of the emerging tandem photovoltaics market
- Coverage of the key and emerging technologies which are receiving industry attention, including perovskite/silicon tandem PV, all-perovskite tandem PV and perovskite/CIGS tandem PV
- Review of the major application areas which can benefit from tandem PV
Market analysis throughout
- Detailed assessment of the entire thin film photovoltaics market, including over 40 company profiles
- Forecasts for the entire thin film PV market for the period 2025-2035 segmented by technology and application area
- In depth cost analysis of each technology type to help formulate market revenue and module price forecasts for the next decade
| Report Metrics | Details |
|---|---|
| Historic Data | 2010 - 2023 |
| CAGR | The thin film photovoltaics market is predicted to exceed US$11 billion, growing at a CAGR of 8% from 2025 to 2035 |
| Forecast Period | 2025 - 2035 |
| Forecast Units | Annual installations (GW), Annual revenue (US$ billions), Unit price ($/W) |
| Segments Covered | Thin film solar technologies (organic, DSSC, perovskite, CdTe, CIGS, amorphous silicon, GaAs, CZTS), tandem perovskite solar technologies (perovskite/silicon, all-perovskite, perovskite/CIGS and perovskite/CdTe), Solar power applications (solar farms, residential rooftop, building integrated PV, wireless electronics, agrivoltaics, automotive), Material trends (substrates, encapsulants and manufacturing methods) |
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| 1. | EXECUTIVE SUMMARY |
| 1.1. | Report introduction |
| 1.2. | What is a solar cell? |
| 1.3. | The solar power market growth |
| 1.4. | Global renewable and solar energy targets |
| 1.5. | What is a thin film solar cell? |
| 1.6. | Thin film PV technologies covered in this report |
| 1.7. | Benchmarking of thin film PV technologies (i) |
| 1.8. | Benchmarking of thin film PV technologies (ii) |
| 1.9. | Solar technology development status (TRL) |
| 1.10. | Thin film PV company landscape by technology type |
| 1.11. | Dye sensitized solar cells overview |
| 1.12. | Organic solar cells overview |
| 1.13. | Perovskite PV - emerging technology set to revive the thin film solar market |
| 1.14. | CdTe PV - dominant thin film technology suffers raw material concerns |
| 1.15. | CIGS PV - could the market be under threat |
| 1.16. | The future of GaAs PV is unknown |
| 1.17. | Amorphous silicon PV has experienced significant market decline |
| 1.18. | Tandem PV technologies to boost efficiencies at little extra cost |
| 1.19. | Manufacturing thin film PV can be scalable and low-cost |
| 1.20. | Cost of photovoltaic technologies |
| 1.21. | The applications for thin film PV |
| 1.22. | Traditional solar applications - rooftops and solar farms |
| 1.23. | Alternative thin film solar applications - Building integration and wireless electronics |
| 1.24. | Could thin-film PV market share increase? |
| 1.25. | Annual solar installation by type |
| 1.26. | Annual thin film PV revenue |
| 1.27. | Outlook for the thin-film PV market |
| 1.28. | Access More With an IDTechEx Subscription |
| 2. | THIN FILM PHOTOVOLTAICS MARKET FORECASTS |
| 2.1. | Forecast methodology |
| 2.2. | Total annual installed solar capacity |
| 2.3. | Total annual thin-film PV installed capacity |
| 2.4. | Annual thin-film PV revenue |
| 2.5. | Annual thin-film installation by application area |
| 2.6. | Annual solar farm installations |
| 2.7. | Annual solar farm revenue |
| 2.8. | Annual residential rooftop installations |
| 2.9. | Annual residential rooftop revenue |
| 2.10. | Annual wireless electronics production capacity |
| 2.11. | Solar module costs |
| 3. | INTRODUCTION |
| 3.1. | What is a solar cell? |
| 3.2. | The solar power market growth |
| 3.3. | Global solar PV investments |
| 3.4. | Current solar installations broken down by region |
| 3.5. | Global renewable and solar energy targets |
| 3.6. | China to remove feed in tariffs |
| 3.7. | Research progression in photovoltaic technology |
| 3.8. | What is a thin film solar cell? |
| 3.9. | Motivation for thin film solar cells |
| 3.10. | Key solar cell performance metrics |
| 3.11. | Thin film PV technologies covered in this report (i) |
| 3.12. | Thin film PV technologies covered in this report (ii) |
| 3.13. | The current thin film solar PV market |
| 3.14. | Could thin-film PV market share increase? |
| 3.15. | Solar technology benchmarking |
| 3.16. | Comparison of major thin film technologies |
| 3.17. | Solar technology development status |
| 3.18. | Thin film PV company landscape |
| 3.19. | Cost of PV technologies |
| 3.20. | Thin film PV benefits from greater vertical integration |
| 4. | EMERGING THIN FILM PHOTOVOLTAIC TECHNOLOGIES |
| 4.1.1. | Introduction to emerging thin film PV |
| 4.1.2. | Emerging thin film PV technology development status |
| 4.2. | Dye sensitized solar cells |
| 4.2.1. | Overview of dye sensitized solar cells |
| 4.2.2. | Interest into DSSCs |
| 4.2.3. | How do DSSCs work? |
| 4.2.4. | DSSC photosensitizer properties |
| 4.2.5. | DSSC electrolyte |
| 4.2.6. | Alternative DSSC electrolyte solutions |
| 4.2.7. | DSSC counter electrodes |
| 4.2.8. | DSSCs stability |
| 4.2.9. | Encapsulation and edge sealing of DSSCs |
| 4.2.10. | Development opportunities for DSSCs |
| 4.2.11. | Dye sensitized solar cells SWOT |
| 4.2.12. | Summary of DSSC technology |
| 4.2.13. | Company landscape |
| 4.2.14. | Exeger overview |
| 4.2.15. | Exeger's Powerfoyle technology applications |
| 4.2.16. | Exeger's commercial partnerships |
| 4.2.17. | Exeger's commercial partnerships continued |
| 4.2.18. | Solaronix overview |
| 4.2.19. | GCell by G24 Power overview |
| 4.3. | Organic solar cells |
| 4.3.1. | Introduction to organic PV |
| 4.3.2. | How do organic solar cells work? |
| 4.3.3. | Organic solar cell fundamental operation |
| 4.3.4. | Advantages and disadvantages of organic PV |
| 4.3.5. | Organic solar cell active layers |
| 4.3.6. | Organic active layer: Small molecules vs polymers |
| 4.3.7. | Non-fullerene acceptors advantages and disadvantages |
| 4.3.8. | Tunability of OPV |
| 4.3.9. | Brilliant Matter's materials used in world-record large area OPV modules |
| 4.3.10. | Current issues to achieving high efficiency large-area modules |
| 4.3.11. | OPV material opportunities |
| 4.3.12. | Organic PV SWOT |
| 4.3.13. | Summary of organic PV |
| 4.3.14. | Organic PV company landscape |
| 4.3.15. | Brilliant Matters - materials supplier |
| 4.3.16. | Brilliant Matters organic PV products |
| 4.3.17. | Raynergy Tek - Materials supplier |
| 4.3.18. | Raynergy's OPV products |
| 4.3.19. | Asca overview |
| 4.3.20. | Asca case studies |
| 4.3.21. | Asca acquired by Hering group |
| 4.3.22. | Epishine overview |
| 4.3.23. | Epishine customers and partnerships |
| 4.3.24. | Dracula Technologies overview |
| 4.3.25. | Dracula Technologies - LAYER OPV technology |
| 4.3.26. | Heliatek overview |
| 4.3.27. | Heliatek installations |
| 4.3.28. | Ribes Tech overview |
| 4.3.29. | Sunew overview |
| 4.3.30. | Organic PV company benchmarking |
| 4.3.31. | Summary of organic PV companies |
| 4.4. | Perovskite photovoltaics |
| 4.4.1. | What is a perovskite solar cell? |
| 4.4.2. | n-i-p vs p-i-n configurations |
| 4.4.3. | Scaffolds used in perovskite PV - Mesoporous perovskite solar cells |
| 4.4.4. | Manufacturing of perovskite PV |
| 4.4.5. | Perovskite stability overview |
| 4.4.6. | Extrinsic degradation |
| 4.4.7. | Intrinsic degradation mechanisms |
| 4.4.8. | Material engineering |
| 4.4.9. | Additive engineering |
| 4.4.10. | Are lead concerns justified? |
| 4.4.11. | Public perception vs reality of lead |
| 4.4.12. | Material composition of perovskites influences optics |
| 4.4.13. | Hole transport materials (HTM) |
| 4.4.14. | Inorganic transport materials |
| 4.4.15. | Recent developments within thin-film perovskite PV |
| 4.4.16. | SWOT analysis of thin film perovskite PV |
| 4.4.17. | Summary - Thin film perovskite PV |
| 4.4.18. | Overview of the thin film perovskite PV market |
| 4.4.19. | Thin film perovskite PV players overview |
| 4.4.20. | Thin film perovskite PV players overview continued |
| 4.4.21. | Saule Technologies overview |
| 4.4.22. | Microquanta overview |
| 4.4.23. | GCL overview |
| 4.4.24. | Renshine Solar overview |
| 4.4.25. | Perovskite thin-film PV major players summary |
| 4.4.26. | Summary of perovskite thin-film major players |
| 4.5. | Applications for emerging thin-film photovoltaics |
| 4.5.1. | Introduction to the applications for emerging thin-film PV |
| 4.5.2. | Current application development stage |
| 4.5.3. | How can thin film perovskite overcome the issues related to silicon PV? |
| 4.5.4. | Indoor energy harvesting and emerging IoT applications |
| 4.5.5. | Companies targeting the IoT and wireless electronics market |
| 4.5.6. | Perovskite PV could be cost-effective alternative for wireless energy harvesting |
| 4.5.7. | Could thin film PV be used in automotive applications? |
| 4.5.8. | Thin-film PV for building integration |
| 4.5.9. | Is BIPV a viable application sector? |
| 4.5.10. | Thin-film PV for building application |
| 4.5.11. | Is perovskite PV a viable option for traditional solar farms? |
| 4.5.12. | Summary of the applications for emerging thin-film PV |
| 5. | INORGANIC THIN-FILM PHOTOVOLTAICS |
| 5.1.1. | Inorganic thin film technologies - alternatives to silicon PV |
| 5.1.2. | Inorganic PV development status |
| 5.2. | Cadmium Telluride (CdTe) photovoltaics |
| 5.2.1. | Introduction to CdTe photovoltaics |
| 5.2.2. | CdTe cell function |
| 5.2.3. | The alternative CdTe PV structure |
| 5.2.4. | CdTe PV buffer layer development |
| 5.2.5. | CdTe PV degradation and doping |
| 5.2.6. | Manufacturing CdTe solar cells |
| 5.2.7. | CdTe PV market share |
| 5.2.8. | Toxicity concerns of CdTe PV |
| 5.2.9. | Tellurium raw material concerns |
| 5.2.10. | Recycling CdTe solar panels |
| 5.2.11. | The steps to recycle CdTe modules |
| 5.2.12. | CdTe vs Silicon PV |
| 5.2.13. | Alternative absorber materials to CdTe |
| 5.2.14. | Material opportunities for CdTe PV |
| 5.2.15. | CdTe PV SWOT |
| 5.2.16. | Summary of CdTe PV technology |
| 5.2.17. | The CdTe PV market overview |
| 5.2.18. | First Solar overview |
| 5.2.19. | First Solar technology and products |
| 5.2.20. | First Solar financials |
| 5.2.21. | First Solar expanding into the perovskite PV market |
| 5.2.22. | Polysolar overview |
| 5.2.23. | CTF Solar overview |
| 5.2.24. | Toledo Solar - emerging player exits market |
| 5.2.25. | Calyxo - bankruptcy history |
| 5.3. | Copper Indium Gallium Selenide (CIGS) photovoltaics |
| 5.3.1. | Introduction to CIGS PV |
| 5.3.2. | How do CIGS solar cells work? |
| 5.3.3. | Improving CIGS solar cell efficiency |
| 5.3.4. | Advantages and disadvantages of CIGS PV |
| 5.3.5. | CIGS vs silicon PV |
| 5.3.6. | Flexible CIGS solar cells |
| 5.3.7. | Manufacturing CIGS PV modules |
| 5.3.8. | The search for simple and low-cost deposition for CIGS PV |
| 5.3.9. | CIGS PV technology opportunities |
| 5.3.10. | CIGS PV SWOT |
| 5.3.11. | Summary of CIGS PV technology |
| 5.3.12. | Overview of CIGS PV market players |
| 5.3.13. | Midsummer overview |
| 5.3.14. | Midsummer partnerships |
| 5.3.15. | Midsummer financials |
| 5.3.16. | Ascent Solar overview |
| 5.3.17. | Ascent Solar financials |
| 5.3.18. | Avancis overview |
| 5.3.19. | Avancis case studies |
| 5.3.20. | Solar Cloth overview |
| 5.3.21. | Sunplugged overview |
| 5.3.22. | CIGS companies overview |
| 5.3.23. | CIGS companies summary |
| 5.4. | Gallium arsenide (GaAs) photovoltaics |
| 5.4.1. | GaAs PV introduction |
| 5.4.2. | GaAs PV operation |
| 5.4.3. | Multi-junction GaAs solar cells |
| 5.4.4. | Properties of GaAs PV |
| 5.4.5. | GaAs PV manufacturing process |
| 5.4.6. | GaAs substrate re-use |
| 5.4.7. | Alternative GaAs PV manufacturing process |
| 5.4.8. | Future of GaAs PV |
| 5.4.9. | GaAs innovation opportunities |
| 5.4.10. | GaAs PV SWOT |
| 5.4.11. | Summary of GaAs PV |
| 5.5. | Amorphous silicon (a-Si) photovoltaics |
| 5.5.1. | Introduction to amorphous silicon PV |
| 5.5.2. | Amorphous silicon PV operation |
| 5.5.3. | Deposition of amorphous silicon |
| 5.5.4. | Amorphous silicon market share decline |
| 5.5.5. | Conventional silicon using amorphous silicon - heterojunction technology |
| 5.5.6. | Photovoltaic thermal collectors |
| 5.5.7. | Onyx Solar overview |
| 5.5.8. | Does amorphous silicon have a future? |
| 5.5.9. | Amorphous silicon PV SWOT |
| 5.5.10. | Amorphous silicon PV summary |
| 5.6. | Copper zinc tin sulfide (CZTS) photovoltaics |
| 5.6.1. | Introduction to CZTS PV |
| 5.6.2. | CZTS PV operating principles |
| 5.6.3. | Cadmium free buffer layers |
| 5.6.4. | CZTS solution-based deposition |
| 5.6.5. | Selenized CZTS - CZTSSe |
| 5.6.6. | CZTS as a hole transport layer - perovskite PV |
| 5.6.7. | Recent kesterite solar cell developments |
| 5.6.8. | Crystalsol - known company working on CZTS commercialization |
| 5.6.9. | CZTS PV SWOT |
| 5.6.10. | Summary of CZTS PV |
| 5.7. | The applications for inorganic thin-film photovoltaics |
| 5.7.1. | Overview of the applications for inorganic thin film PV |
| 5.7.2. | Solar farms rely on cheap and high efficiency solar modules |
| 5.7.3. | Rooftop application of thin-film PV |
| 5.7.4. | BIPV - a more niche application area |
| 5.7.5. | Automotive applications for thin-film PV |
| 5.7.6. | Agrivoltaics - a relatively novel application area |
| 5.7.7. | Summary of the applications for inorganic thin film PV |
| 6. | MANUFACTURING THIN FILM PHOTOVOLTAICS |
| 6.1. | Deposition techniques for scalable processing |
| 6.2. | Sputtering |
| 6.3. | Aerosol assisted chemical vapor deposition |
| 6.4. | Inkjet printing |
| 6.5. | Blade coating |
| 6.6. | Slot-die coating |
| 6.7. | Spray coating |
| 6.8. | Comparison of deposition methods |
| 6.9. | How to choose a deposition method |
| 6.10. | Roll-to-roll printing - scaling up of production and lowering of costs |
| 6.11. | Thin-film PV market use of deposition methods |
| 6.12. | Summary of deposition methods |
| 7. | MATERIALS FOR THIN FILM PHOTOVOLTAICS |
| 7.1. | Introduction - Substrates and encapsulants for thin film PV |
| 7.2. | Substrates - conventional and emerging |
| 7.3. | Rigid glass substrates |
| 7.4. | Alternative substrates to rigid glass |
| 7.5. | Flexible glass substrates |
| 7.6. | Ultra-thin glass can improve flexibility |
| 7.7. | Benefits of ultra-thin glass encapsulation |
| 7.8. | Corning Willow flexible glass |
| 7.9. | Schott Solar flexible glass |
| 7.10. | NEG G-Leaf™ - ultra thin glass |
| 7.11. | Plastic substrates |
| 7.12. | Plastic substrates require barrier layers |
| 7.13. | Metal foil substrates |
| 7.14. | Substrate surface roughness |
| 7.15. | Substrate material supply opportunities |
| 7.16. | Cost comparison of substrate materials |
| 7.17. | Benchmarking of substrate materials |
| 7.18. | Choosing a substrate material |
| 7.19. | Glass-glass encapsulation |
| 7.20. | What properties are required for a good optical encapsulant material? |
| 7.21. | Polymer encapsulation |
| 7.22. | Traditional thin film encapsulation |
| 7.23. | Emerging thin film encapsulant - Al2O3 |
| 7.24. | Ergis noDiffusion® ultra barrier film |
| 7.25. | Commercially available flexible encapsulants |
| 7.26. | Material opportunities for substrates and encapsulants |
| 7.27. | Summary of thin-film PV substrates and encapsulants |
| 8. | TANDEM PHOTOVOLTAICS |
| 8.1.1. | Introduction to tandem PV |
| 8.1.2. | Single junction vs tandem solar cells |
| 8.1.3. | Tandem solar cells surpass the theoretical efficiency limits of single junction cells |
| 8.2. | Perovskite/silicon tandem photovoltaics |
| 8.2.1. | Overview of perovskite on silicon tandem PV |
| 8.2.2. | Perovskite/silicon tandem advantages |
| 8.2.3. | Perovskite/Si tandem structure and configurations |
| 8.2.4. | 2-terminal and 4-terminal tandem cell comparison |
| 8.2.5. | Challenges with tandem cell configurations |
| 8.2.6. | Interconnection layer for 2-terminal tandem cells |
| 8.2.7. | Tandem cell fabrication process |
| 8.2.8. | Perovskite/silicon tandem PV roadmap |
| 8.2.9. | Perovskite/silicon tandem PV SWOT |
| 8.2.10. | Summary of perovskite/silicon tandem PV |
| 8.2.11. | Overview of the perovskite/silicon tandem PV market |
| 8.2.12. | Major companies targeting both perovskite thin film and perovskite/silicon tandem technology |
| 8.2.13. | Overview of the perovskite tandem PV players |
| 8.2.14. | Overview of the perovskite tandem PV players |
| 8.3. | All-perovskite tandem photovoltaics |
| 8.3.1. | All perovskite tandem solar cell technological advancements |
| 8.3.2. | Perovskite/perovskite tandem solar cell band gap tuning |
| 8.3.3. | Perovskite/perovskite tandem solar cell architectures and manufacturing |
| 8.3.4. | Wide band gap perovskite challenges |
| 8.3.5. | Use of Sn poses a key challenge |
| 8.3.6. | HTL free perovskite solar cells |
| 8.3.7. | Carbon-based HTL-free perovskite solar cells |
| 8.3.8. | All perovskite tandem solar cells advantages and disadvantages |
| 8.3.9. | All perovskite tandem PV SWOT |
| 8.3.10. | Summary of all-perovskite tandem PV |
| 8.3.11. | Renshine Solar targeting the future commercialization of all-perovskite tandem technology |
| 8.3.12. | Energy Materials Corporation - A thin-film perovskite player to target the tandem market |
| 8.4. | Other tandem perovskite photovoltaic technologies |
| 8.4.1. | Introduction to perovskite/CIGS tandem PV |
| 8.4.2. | Perovskite/CIGS tandem PV cell fabrication and structure |
| 8.4.3. | Midsummer develops 4-terminal perovskite/CIGS solar cell |
| 8.4.4. | First Solar exploring perovskite tandem PV |
| 8.4.5. | Perovskite/CIGS tandem PV SWOT |
| 8.4.6. | Perovskite/CdTe tandem PV overview |
| 8.4.7. | Summary of alternative perovskite tandem PV technologies |
| 8.5. | Applications for tandem photovoltaics |
| 8.5.1. | Technology choice for different applications |
| 8.5.2. | Tandem PV for roof tops |
| 8.5.3. | Tandem PV to boost utility solar farm power |
| 8.5.4. | Could perovskite/silicon tandem PV be used for windows? |
| 8.5.5. | All-perovskite tandem for solar powered vehicles |
| 8.5.6. | Summary of the applications for tandem PV |
| 9. | COMPANY PROFILES |
| 9.1. | Ascent Solar |
| 9.2. | Avancis |
| 9.3. | Beyond Silicon |
| 9.4. | Caelux |
| 9.5. | Cosmos Innovation |
| 9.6. | Coveme: Photovoltaics |
| 9.7. | Crystalsol |
| 9.8. | CubicPV |
| 9.9. | Dracula Technologies |
| 9.10. | Dracula Technologies |
| 9.11. | Energy Materials Corporation |
| 9.12. | Energy Materials Corporation |
| 9.13. | Epishine |
| 9.14. | Epishine |
| 9.15. | Epishine |
| 9.16. | Exeger |
| 9.17. | GCL |
| 9.18. | GraphEnergyTech |
| 9.19. | Hanwha Qcells (Perovskite) |
| 9.20. | Heliatek |
| 9.21. | Heliatek |
| 9.22. | Hiking PV |
| 9.23. | Microquanta Semiconductor |
| 9.24. | Midsummer |
| 9.25. | Onyx Solar |
| 9.26. | Opteria |
| 9.27. | Oxford PV |
| 9.28. | Perovskia Solar |
| 9.29. | Polysolar |
| 9.30. | Power Roll |
| 9.31. | Raynergy Tek: Photovoltaics |
| 9.32. | Renshine Solar |
| 9.33. | Ribes Tech |
| 9.34. | Saule Technologies |
| 9.35. | SCHOTT |
| 9.36. | Solaronix |
| 9.37. | Sunplugged |
| 9.38. | Swift Solar |
| 9.39. | Tandem PV |
| 9.40. | Toledo Solar |
| 9.41. | Victrex |
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2025年-2035年薄膜光伏市场:技术、参与者和趋势
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到2035年,薄膜光伏市场(规模)预计将超过110亿美元。
报告统计信息
| 幻灯片 | 349 |
|---|---|
| Companies | 41 |
| 预测 | 2035 |
| 已发表 | Mar 2025 |
预览内容
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