市場調查報告書
商品編碼
1273618
到 2028 年的鈣鈦礦太陽能電池市場預測 - 按結構、產品、方法、應用、最終用戶和地區進行的全球分析Perovskite Solar Cell Market Forecasts to 2028 - Global Analysis By Structure, Product, Method, Application, End User and Geography |
根據Stratistics MRC,2022年全球鈣鈦礦太陽能電池市場規模將達到8億美元,預計2028年將達到46億美元,預測期內增長33.8%。預計將以復合年增長率增長。
鈣鈦礦太陽能電池是一種最新型的柔性輕型光伏電池。 鈣鈦礦太陽能電池的光捕獲活性層由鈣鈦礦結構化合物、鹵化錫基材料和有機-無機雜化鉛組成。 鈣鈦礦太陽能電池近年來有了很大的改進,因為隨著太陽能的進步,它們使用的設備效率很高。
根據國際可再生能源協會的信息,2020 年 4 月,非洲聯盟理事會 (AUC) 和 IRENA 簽署了一項關於開發太陽能電池板農場或其他包含分佈式系統的可再生技術的協議。底部。
鈣鈦礦是最新的太陽能電池材料,具有適合吸收太陽能的晶體結構。 此外,鈣鈦礦電池在弱光、陰天或室內的性能優於矽,從而實現更高的轉換效率。 基於鈣鈦礦的太陽能電池的一個基本優勢是它們價格便宜且材料豐富,可以實現廉價的光伏發電。 由於鈣鈦礦太陽能電池具有優於傳統太陽能電池的性能,因此太陽能電池公司致力於開發和商業化鈣鈦礦太陽能電池。 參與鈣鈦礦太陽能電池開發的公司正在尋求研究和發明資金。 鈣鈦礦太陽能電池的研發持續投資,市場進入者有擴張前景。
鈣鈦礦在與氧氣或濕氣發生反應,或者長時間暴露在光、熱或電流下時會發生降解。 鈣鈦礦研發 (R&D) 社區正在研究各種方法來理解和改進穩定性和降解,重點是延長使用壽命。 該研究的目標是降低鈣鈦礦表面的反應性,同時確定鈣鈦礦材料成分的替代品。
與傳統太陽能電池相比,鈣鈦礦太陽能電池具有具有競爭力的功率轉換效率 (PCE) 和潛在的更高性能。 無論陽光是自然的還是人造的,鈣鈦礦太陽能電池都可以將其轉化為能量。 與傳統太陽能電池相比,鈣鈦礦太陽能電池具有多項優勢,包括製造成本低得多和更薄。 鈣鈦礦太陽能電池具有出色的光譜吸收能力,即使在弱光和不規則光照下也能表現出高效率。
高昂的製造成本預計會限制增長。 原材料成本的波動預計也會在整個預測期內阻礙鈣鈦礦太陽能行業。 這份鈣鈦礦太陽能電池板行業報告涵蓋了最新發展、進口限制、進出口分析、公司結構、價值鏈增強、客戶群、家庭和區域市場進入者的影響、收入等級變化的潛力。它提供了分析信息,限制修正、重大市場擴張分析、市場份額、市場過度增長分類、利基市場實施和國內市場支配地位。
幾乎每個行業都受到 COVID-19 的極大影響,包括電子、半導體、製造業和汽車。 然而,客戶對技術服務需求的顯著轉變推動了許多技術相關業務的收入增長。 由於這一流行病,富裕國家和發展中國家也取得了重大的技術進步。
據估計,介孔鈣鈦礦太陽能電池領域的增長利潤豐厚。 與由其他材料製成的對應物相比,介孔鈣鈦礦太陽能電池由於具有更高的穩定性和效率而變得越來越流行。 中孔結構允許更高的光吸收和更好的電荷轉移,從而提高轉換效率。 此外,正在進行研發工作以提高介孔鈣鈦礦太陽能電池的穩定性和效率。 隨著技術的發展,未來介孔市場有望顯著擴大。
在預測期內,光伏建築一體化 (BIPV) 領域預計將以最快的複合年增長率增長。 光伏建築一體化(BIPV)在屋頂、天窗、外立面等建築外牆用光伏材料替代傳統建築材料,增加了對BPIV的需求,從而推動了市場發展。
由於城市化進程加快、對可再生能源的需求最小化對化石燃料的依賴以及政府支持的增加,預計亞太地區在預測期內將佔據最大的市場份額。 此外,由於該地區家電行業的發展,市場正在擴大。
由於太陽能產量增加以及與改進鈣鈦礦電池開發相關的研發支出增加,預計北美在預測期內的複合年增長率最高。 北美市場進入者正在尋找通過生產效率進一步降低太陽能電池板成本的方法。
2019 年 8 月,總部位於英國的專注於鈣鈦礦的 Oxford PV 公司從瑞士科技公司 Meyer Burger 購買了第一台太陽能電池製造機器。 到2020年底,牛津光伏擬收購一座250MW的鈣鈦礦專用組裝設施。
According to Stratistics MRC, the Global Perovskite Solar Cell Market is accounted for $0.8 billion in 2022 and is expected to reach $4.6 billion by 2028 growing at a CAGR of 33.8% during the forecast period. One of the newest types of photovoltaic cells that are flexible and lightweight is perovskite solar cells. The light-harvesting active layer of a perovskite solar cell is made up of a perovskite-structured compound, tin halide-based substance, and hybrid organic-inorganic lead. Due to ongoing advancements in solar energy, perovskite solar cells have a high efficiency in devices utilising them and have seen major improvements in recent years.
According to information provided by the International Renewable Power Association, the African Union Council (AUC) and IRENA inked an agreement in April 2020 for the development of solar panels farms or other renewable technology incorporating decentralized systems.
The newest solar material, perovskite, has a crystal structure that is good for absorbing solar energy. Additionally, perovskite cells outperform silicon in lower lighting levels, on overcast days, or indoors, allowing for higher conversion efficiencies. The fundamental advantage of using perovskite to create solar cells is that it is an affordable, plentiful material that can generate inexpensive solar electricity. Organisations in the solar cell business are attempting to create and commercialise perovskite solar cells because they have advantages over conventional cells. Companies engaged in the development of perovskite solar cells are soliciting money for study and invention. Perovskite solar cell research and development are receiving ongoing investment, which is presenting market participants with expansion prospects.
When perovskites react with oxygen and moisture or are exposed for a lengthy period of time to light, heat, or electrical current, they can degrade. The perovskite research and development, or R&D, community is working on a variety of ways to comprehend and better stabilise and degrade, with a strong emphasis on increasing operational lifespan. The goal of the research is to make perovskite surfaces less reactive while also identifying substitute materials for perovskite material compositions.
Compared to conventional solar cells, perovskite solar cells offer competitive power conversion efficiencies (PCE) and the potential for greater performance. Regardless of whether the sunlight is natural or manufactured, perovskite solar cells can still convert it into energy. Perovskite solar cells have several advantages over conventional solar cells, including being far more affordable to manufacture and thinner. Perovskite solar cells have superior spectrum absorption and enable greater efficiency in low and erratic lighting.
High production costs are expected to restrict growth. Changes in raw material costs are also projected to be an obstacle to the perovskite solar energy industry throughout the projection period. This report on the perovskite solar panel industry provides information on the most recent trends, import restrictions, import and export analysis, company structure, value chain enhancement, customer base, the impact of household and local market participants, analysis of possibilities in relation to changing income sections, modifications in the restrictions, significant market expansion analysis, market shares, classification of market overgrowth, implementation of niche markets, and supremacy of the domestic market.
Almost every industry, including electronics, semiconductors, manufacturing, automobiles, etc., was significantly impacted by COVID-19. However, due to substantial shifts in customer demand for technical services, a number of technology-related businesses have witnessed a growth in revenue. Additionally, both rich and developing nations have seen substantial technological advancements as a result of the epidemic.
The mesoporous perovskite solar cells segment is estimated to have a lucrative growth. Mesoporous perovskite solar cells are also becoming more popular because they provide more stability and efficiency compared to their equivalents made of other materials. Higher light absorption and better charge transfer are made possible by the mesoporous structure, which increases conversion efficiency. Additionally, efforts are being made in research and development to increase the stability and efficiency of mesoporous perovskite solar cells. With technological developments, the mesoporous market is anticipated to expand significantly in the years to come.
The Building Integrated Photovoltaics (BIPV) segment is anticipated to witness the fastest CAGR growth during the forecast period. Building-integrated photovoltaic materials (BIPV) replace traditional building materials with photovoltaic ones in building envelopes including roofs, skylights and facades, increasing demand for BPIV and hence driving market development.
Asia Pacific is projected to hold the largest market share during the forecast period owing to the region's rising urbanisation, the need for renewable energy sources to minimise reliance on fossil fuels, and growing government backing. Additionally, the region's market is growing due to the region's well-developed consumer electronics industry.
North America is projected to have the highest CAGR over the forecast period, owing to rising solar energy output and rising expenditures in R&D initiatives related to the creation of improved perovskite cells. Participants in the North American market are looking for methods to further reduce the costs of these solar panels by streamlining production.
Some of the key players profiled in the Perovskite Solar Cell Market include: Fujikura, Kyocera, BASF, Panasonic, Merck, LG Chem, Toshiba, FrontMaterials Co. Ltd., Polyera Corporation and Greatcell Energy.
In August 2019, Oxford PV, a perovskite-focused company based in the UK, purchased the first piece of solar cell production machinery from Meyer Burger, a Swiss technology company. By the end of 2020, Oxford PV intends to acquire a 250 MW perovskite special assembly facility.
Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.