Perovskite Solar - Page 30

Reports suggest that China-based GCL (via its new subsidiary Kunshan GCL Photoelectric Materials) will establish its integrated project relating to the perovskite and energy storage industries in Kunshan. The GCL Group is an international energy group mainly focused on new energy, clean energy and related industries. It has been listed in the Top 500 Chinese Enterprises and the Top 500 Private Enterprises in China for many consecutive years, ranking second in the top 500 global new energy companies. 

The comprehensive cooperation reached betweenGCL and Kunshan's government involves projects related to perovskite, energy storage, digital energy, and the digital technology financial center. With the support of Kunshan's government, GCL Perovskite will build the world's first large-scale 2GW perovskite production line in two phases, aiming to create a billion-level industrial base.

Researchers at China's Wuhan University of Technology, Huazhong University of Science and Technology and Jinan Municipal Bureau of Industry and Information Technology have developed a novel playdough-like graphite putty as top electrode for perovskite solar devices. The electrode is malleable and so can form good contact with the hole-transporting layer and the conductive substrate at room temperature using a simple pressing technique, which facilitates the fabrication of both small-area devices and perovskite solar modules. 

Carbon-based perovskite solar cells (C-PSCs) are promising candidates for large-scale photovoltaic applications due to their theoretical low cost and high stability. However, the fabrication of high-performance C-PSCs with large-area electrodes remains challenging. In their recent research, the team showed that corresponding small devices and modules can achieve efficiencies of 20.29% (∼0.15 cm²) and 16.01% (∼10 cm²), respectively. Moreover, they analyzed the limitations of the optical and electrical properties of this playdough-like graphite electrode on the device performance, suggesting a direction for further improvement of C-PSCs in the future.

China's Three Gorges Group has announced that "the world's first commercial megawatt-level perovskite ground-mounted photovoltaic project was successfully connected to the grid on November 29".

The project is located in the Kubuqi Desert hinterland of Hangjin Banner, Ordos City, Inner Mongolia, and is supported by the Kubuqi 2 million kilowatt photovoltaic desert control project in the west of Inner Mongolia. The project has an installed capacity of 1 megawatt, covers an area of 40 acres, and utilizes a total of 11,200 modules of perovskite photovoltaic modules, as was reported.

Hanwha Qcells recently announced it will be closing its 3.5GW module factory in South Korea, in response to the stagnant solar market in the country. It was reported that the total installed capacity of solar power in South Korea has been continuously decreasing over the past three years, from 4.7GW in 2020 to 3.4GW in 2022, and is expected to further decrease in 2023.

Closing the factory comes as part of a plan to optimize Hanwha's photovoltaic module production capacity. However, Hanwha stated that it will continue to invest in its factory in Jincheon, South Korea, which will continue to produce TOPCon products and operate a perovskite tandem cell pilot line.

Researchers at South Korea’s Chonnam National University have reported perovskite-organic hybrid tandem solar cells with 23.07% efficiency processed entirely in open air, bringing the technology a step closer to economic viability.

Schematic illustration of the synthesis of all-inorganic perovskite thin films by dynamic hot-air-assisted method. Image from Energy & Environmental Science 

Researchers have largely relied on meticulously engineering the perovskite crystal structure itself for greater resilience. But these delicate handling steps add cost and complexity not suitable for mass production. The team explained that the focus has recently shifted toward all-solution processed solar cells due to their low energy consumption fabrication processes. The team’s innovation, a dynamic hot air deposition technique, simplified the production process by eliminating the need for humidity-controlled environments.

Researchers at Germany’s Fraunhofer ISE have estimated that the practical power conversion efficiency potential of perovskite-silicon tandem solar cells may reach up to 39.5%. In a recent study, the Fraunhofer ISE scientists set out to provide guidelines for future research on perovskite-silicon tandem solar cells by identifying the most significant loss mechanisms at the perovskite/ETL interface, in the series resistance, and in light management.

The team explained that the calculated practical efficiency potential of 39.5% for a perovskite silicon tandem device under standard measurement conditions (STC) can serve as an input for future studies which are required for a better understanding of the full system before the commercialization of tandem solar cell technology can take place.

It was reported that China-based Ideal Deposition Equipment, a technology and equipment company with chemical vapor deposition technology as its core, has entered into a supply agreement with a top American photovoltaic company for manufacturing perovskite cells.

Ideal Deposition primarily focuses on producing equipment for PERC and TOPCon production. In recent years, it has launched a series of related equipment for mainstream photovoltaic cell producers worldwide. Additionally, it manufactures coating equipment for tandem layers of perovskite cells.

China-based BOE Technology Group (BOE), one of the leading companies in the global display technology field, recently launched a project to enter the photovoltaic industry by investing in perovskite solar cells. BOE held a ceremony to launch the project

It is believed that BOE's entry into the perovskite solar cell market will bring new energy to the industry, which is in line with the country's renewable energy policy. The Company has a strong R&D team and extensive experience in display technologies, which could be applied to the development of perovskite solar cells. BOE has also established partnerships with top universities and research institutions to promote the development of perovskite solar cells.

Researchers from the Indian Institute of Science Education and Research Thiruvananthapuram (IISER-TVM), Germany's University of Potsdam and The Chinese University of Hong Kong have addressed an important aspect in the field of perovskite solar cells (PSCs) – the exact role of excess lead iodide content within the perovskite layer. While an optimal amount of excess lead iodide contributes to improved grain boundary passivation and blocking of minority charge carriers, leading to the development of highly efficient PSCs, the photo-stability of PSCs with surplus lead iodide remains a major concern. This concern stems from the catalytic role excess lead iodide can play in the degradation of PSCs under illumination.

The issue often arises during the fabrication of perovskite films using a two-step spin coating method, where the conversion of lead iodide films to perovskite is hindered due to challenges in controlling the reaction between lead iodide films and cationic precursor solutions. Various modifications of the two-step approach are presented in the literature, each aiming to achieve a near full conversion of lead iodide films into perovskite when exposed to cationic precursor solutions.

GCL Photoelectric Materials (GCL Perovskite), a subsidiary of GCL Tech, has announced that it was able to attain a photoelectric conversion efficiency of 18.04% on a perovskite single-junction solar module, with dimensions measuring 1,000mm by 2,000mm. It was reported that this result was officially tested and confirmed by the China National Institute of Metrology.

GCL Perovskite team has been working on achieving this objective of exceeding the anticipated conversion efficiency of 18% for standard-sized perovskite modules, and the team will now focus on conducting research and development for the next-generation perovskite tandem modules.