Perovskite Solar
What are perovskite?
Perovskites are a class of materials that share a similar structure, which display a myriad of exciting properties like superconductivity, magnetoresistance and more. These easily synthesized materials are considered the future of solar cells, as their distinctive structure makes them perfect for enabling low-cost, efficient photovoltaics. They are also predicted to play a role in next-gen electric vehicle batteries, sensors, lasers and much more.
How does the PV market look today?
In general, Photovoltaic (PV) technologies can be viewed as divided into two main categories: wafer-based PV (also called 1st generation PVs) and thin-film cell PVs. Traditional crystalline silicon (c-Si) cells (both single crystalline silicon and multi-crystalline silicon) and gallium arsenide (GaAs) cells belong to the wafer-based PVs, with c-Si cells dominating the current PV market (about 90% market share) and GaAs exhibiting the highest efficiency.
Thin-film cells normally absorb light more efficiently than silicon, allowing the use of extremely thin films. Cadmium telluride (CdTe) technology has been successfully commercialized, with more than 20% cell efficiency and 17.5% module efficiency record and such cells currently hold about 5% of the total market. Other commercial thin-film technologies include hydrogenated amorphous silicon (a-Si:H) and copper indium gallium (di)selenide (CIGS) cells, taking approximately 2% market share each today. Copper zinc tin sulphide technology has been under R&D for years and will probably require some time until actual commercialization.
What is a perovskite solar cell?
An emerging thin-film PV class is being formed, also called 3rd generation PVs, which refers to PVs using technologies that have the potential to overcome current efficiency and performance limits or are based on novel materials. This 3rd generation of PVs includes DSSC, organic photovoltaic (OPV), quantum dot (QD) PV and perovskite PV.
A perovskite solar cell is a type of solar cell which includes a perovskite structured compound, most commonly a hybrid organic-inorganic lead or tin halide-based material, as the light-harvesting active layer. Perovskite materials such as methylammonium lead halides are cheap to produce and relatively simple to manufacture. Perovskites possess intrinsic properties like broad absorption spectrum, fast charge separation, long transport distance of electrons and holes, long carrier separation lifetime, and more, that make them very promising materials for solid-state solar cells.
Perovskite solar cells are, without a doubt, the rising star in the field of photovoltaics. They are causing excitement within the solar power industry with their ability to absorb light across almost all visible wavelengths, exceptional power conversion efficiencies already exceeding 20% in the lab, and relative ease of fabrication. Perovskite solar cells still face several challenge, but much work is put into facing them and some companies, are already talking about commercializing them in the near future.
What are the advantages of Perovskite solar cells?
Put simply, perovskite solar cells aim to increase the efficiency and lower the cost of solar energy. Perovskite PVs indeed hold promise for high efficiencies, as well as low potential material & reduced processing costs. A big advantage perovskite PVs have over conventional solar technology is that they can react to various different wavelengths of light, which lets them convert more of the sunlight that reaches them into electricity.
Moreover, they offer flexibility, semi-transparency, tailored form factors, light-weight and more. Naturally, electronics designers and researchers are certain that such characteristics will open up many more applications for solar cells.
What is holding perovskite PVs back?
Despite its great potential, perovskite solar cell technology is still in the early stages of commercialization compared with other mature solar technologies as there are a number of concerns remaining.
One problem is their overall cost (for several reasons, mainly since currently the most common electrode material in perovskite solar cells is gold), and another is that cheaper perovskite solar cells have a short lifespan. Perovskite PVs also deteriorate rapidly in the presence of moisture and the decay products attack metal electrodes. Heavy encapsulation to protect perovskite can add to the cell cost and weight. Scaling up is another issue - reported high efficiency ratings have been achieved using small cells, which is great for lab testing, but too small to be used in an actual solar panel.
A major issue is toxicity - a substance called PbI is one of the breakdown products of perovskite. This is known to be toxic and there are concerns that it may be carcinogenic (although this is still an unproven point). Also, many perovskite cells use lead, a massive pollutant. Researchers are constantly seeking substitutions, and have already made working cells using tin instead. (with efficiency at only 6%, but improvements will surely follow).
What’s next?
While major challenges indeed exist, perovskite solar cells are still touted as the PV technology of the future, and much development work and research are put into making this a reality. Scientists and companies are working towards increasing efficiency and stability, prolonging lifetime and replacing toxic materials with safer ones. Researchers are also looking at the benefits of combining perovskites with other technologies, like silicon for example, to create what is referred to as “tandem cells”.
Commercial activity in the field of perovskite PV
In September 2015, Australia-based organic PV and perovskite solar cell (PSC) developer Dyesol declared a major breakthrough in perovskite stability for solar applications. Dyesol claims to have made a significant breakthrough on small perovskite solar cells, with “meaningful numbers” of 10% efficient strip cells exhibiting less than 10% relative degradation when exposed to continuous light soaking for over 1000 hours. Dyesol was also awarded a $0.5 million grant from the Australian Renewable Energy Agency (ARENA) to commercialize an innovative, very high efficiency perovskite solar cell.
Also in 2015, Saule Technologies signed an investment deal with Hideo Sawada, a Japanese investment company. Saule aims to combine perovskite solar cells with other currently available products, and this investment agreement came only a year after the company was launched.
In October 2020, Saule launched sunbreaker lamellas equipped with perovskite solar cells. The product is planned to soon be marketed across across Europe and potentially go global after that.
In August 2020, reports out of China suggested that a perovskite photovoltaic cell production line has gone into production in Quzhou, east China's Zhejiang Province. The 40-hectare factory was reportedly funded by Microquanta Semiconductor and expected to produce more than 200,000 square meters of photovoltaic glass before the end of 2020.
In September 2020, Oxford PV's Professor Henry Snaith stated that the Company's perovskite-based solar cells are scheduled to go on sale next year, probably by mid 2021. These will be perovskite solar cells integrated with standard silicon solar cells.
New method uses indium oxide buffer layer for improved for perovskite/Si 4-terminal tandem solar cells
The fabrication of perovskite/Si tandem solar cells often encounters the challenge of selecting a suitable sputtering buffer layer (SBL) to prevent damage during the transparent electrode deposition. In their recent work, researchers from China's Northwestern Polytechnical University and Shaanxi Joint Laboratory of Graphene (NPU), Chinese Academy of Sciences and Ningbo New Materials Testing and Evaluation Center Co. developed a perovskite-silicon tandem solar cell that uses an indium oxide sputtering buffer layer to protect the perovskite absorber and the electron transport layer from damages that might occur during the electrode deposition process. The new layer not only granted this protection but also showed strong optical and electrical properties.
The team introduced the indium oxide (In2O3) buffer layer via e-beam deposition to fabricate semi-transparent perovskite solar cells. The optical transmittance and electrical conductivity of In2O3 highly depend on the deposition rate. High deposition rate results in high ratio of metallic indium in the film, which causes severe parasitic absorption. A 20 nm-thick In2O3 film deposited at lower rate demonstrated high conductivity, transmittance and robust protection during sputtering.
Power Roll partners with Amcor on solar PV film
Power Roll, developer of flexible PVs that feature a unique combination of microgrooves and perovskites, has signed a Memorandum of Understanding (MOU) with Amcor, a global packaging solutions provider.
Power Roll and Amcor’s collaboration will be focused on advancing solar-powered energy by developing a lightweight solar photovoltaic film that aims to deliver a low-cost alternative to silicon solar panels. The company has a clear focus on capitalizing on growing market opportunities, focusing on the commercialization of its solar PV microgroove technology, which is not reliant on rare earth minerals and can be manufactured using roll-to-roll processes.
Researchers present 23.2% efficient low band gap perovskite solar cells using cyanogen management method
An international team of researchers, led by the University of Surrey with Imperial College London, recently reported a strategy to improve both the performance and stability for perovskite solar cells by mitigating a previously hidden degradation pathway.
In their new study, the scientists detail how they produced lead-tin perovskite solar cells that reach more than 23% power conversion efficiency (PCE) – which the team says is one of the best results achieved with this material and importantly, a design strategy which improves the lifetime of these devices by 66%.
Researchers gain better understanding of perovskite solar cells
Bifacial perovskite solar cells (Bi-PSCs) have attracted substantial attention due to their potential for enhanced power generation, suitability for integration into building structures and applicability in multijunction PV systems. Recently, researchers from the Indian Institute of Technology Bombay reported the fabrication of efficient Bi-PSCs and investigated their unique properties using various characterization techniques, including Lambertian reflection effects through tilt angle arrangements and bottom albedo illuminations.
The control device achieved a maximum power conversion efficiency (PCE) of 17.46% under front-side 1 Sun AM1.5G illumination. A significant influence of ground Lambertian reflection was observed with tilt angle variations, resulting in an increase in PCE from 17.46% → 18.82% as the tilt angle reached 20°. Additionally, enhancing the rear-side albedo to 0.5 Sun yielded a maximum PCE of 26% with a bifaciality factor of ∼90% at a tilt angle of 20°.
Novel approach manages iodine migration to improve stability of inverted single-junction and tandem perovskite solar cells
Chinese Academy of Sciences (CAS) researchers believe that the issue of instability of perovskite solar cells (PSCs) primarily originates from the migration of halide ions—particularly iodide ions (I−). Under light exposure and thermal stress, I− migrates and transforms into I2, leading to irreversible degradation and performance loss.
To tackle this challenge, the team introduced the additive 2,1,3-benzothiadiazole,5,6-difluoro-4,7-bis(4,4,5,5-tetramethyl-1,3,2-dioxaborolan-2-yl) (BT2F-2B) into the perovskite. The strong coordination between the unhybridized p orbital and lone-pair electrons from I− inhibits the deprotonation of MAI/FAI and the subsequent conversion of I− to I₂. The highly electronegative fluorine enhances its electrostatic interaction with I−. Consequently, the synergistic effect of BT2F-2B effectively suppresses the decomposition of perovskite and the defect density of the iodide vacancies.
Novel one-step encapsulation approach addresses both optical losses and extrinsic stability issues simultaneously
Researchers at Finland's Aalto University and Tampere University have developed an encapsulation method for perovskite solar cells (PSCs) to address both optical performance losses at the air-cell interface and intrinsic and extrinsic stability challenges. The team's one-step method provides PSCs with shielding from oxygen and moisture-induced degradation as well as in situ patterning for light management.
In the new method, the entire surface and sides of the solar cells were coated with polydimethylsiloxane (PDMS), and the front-facing surface of the PSC was in situ–patterned using a soft lithography technique. A replica of leek leaf surface structures was created on the PDMS to reduce reflection and increase haze. The scientists explained that leek leaf replicas, previously used as add-on layers for PSC devices, have shown promise due to their optical and self-cleaning properties.
CityUHK researchers receive NSFC funding to promote high-performance perovskite/organic tandem solar cells
Three research projects by City University of Hong Kong (CityUHK) scholars have been awarded funding under the 2024/25 National Natural Science Foundation of China (NSFC) and the Research Grants Council (RGC) Collaborative Research Scheme (CRS), amounting to over HK$8.8 million (around USD$1,130,000). Additionally, five CityUHK scholars have been awarded funding from the 2024/25 NSFC/RGC Joint Research Scheme (JRS), with total funding exceeding HK$6 million (over USD$770,000).
Among the CityUHK research projects awarded funding under the Collaborative Research Scheme is “Theoretically Guided Material Design, Syntheses and Device Engineering for Efficient and Stable Perovskite/Organic Tandem Solar Cells”, led by Professor Zeng Xiaocheng, Head and Chair Professor of the Department of Materials Science and Engineering, which aims to develop high-performance perovskite/organic tandem solar cells with efficiencies exceeding 28%, promoting the development of sustainable clean energy while advocating global carbon neutrality.
UtmoLight develops 450W perovskite solar module with 16.1% efficiency
It was reported that China-based UtmoLight has developed a 450 W perovskite solar module with a 16.1% efficiency rating. It claims that the panel is currently the largest perovskite PV module available.
The new module reportedly covers an area of 2.8 square meters, uses dual-glass encapsulation and features an open-circuit voltage of 190.7 V, a short-circuit current of 3.19, and a fill factor of 73.7%.
Researchers tweak perovskite precursor solutions to produce useful cations that improve perovskite solar modules
Researchers from Ecole Polytechnique Fédérale de Lausanne (EPFL), North China Electric Power University, Westlake University, Lomonosov Moscow State University and others have described the addition of N,N-dimethylmethyleneiminium chloride ([Dmei]Cl) into perovskite precursor solutions to produce two cations in situ—namely 3-methyl-2,3,4,5-tetrahydro-1,3,5-triazin-1-ium ([MTTZ]+) and dimethylammonium ([DMA]+) cations - that enhanced the photovoltaic
performance and stability of perovskite solar modules.
A schematic of the roles of [MTTZ]+ and [DMA]+ in the 3D perovskite matrix. Image from: Science
The team explained that the in situ formation of [MTTZ]+ cation increased the formation energy of iodine vacancies and enhanced the migration energy barrier of iodide and cesium ions, which suppressed nonradiative recombination, thermal decomposition, and phase segregation processes.
Researchers examine homogeneous 2D perovskite passivation layer and achieve positive results
The formation of a homogeneous passivation layer based on phase-pure two-dimensional (2D) perovskites is a challenge for perovskite solar cells, especially when upscaling the devices to modules. Researchers from China's Wuhan University of Technology, Xidian University, University of Electronic Science and Technology of China and Germany's Technical University of Munich have revealed a chain-length-dependent and halide-related phase separation problem of 2D perovskite growing on top of three-dimensional perovskites.
The scientists have demonstrated that a homogeneous 2D perovskite passivation layer can be formed upon treatment of the perovskite layer with formamidinium bromide in long-chain ( >10) alkylamine ligand salts.
