Perovskite Solar

Researchers at the University of Toledo have designed a four-terminal (4T) tandem solar cell with a top device that uses a perovskite absorber with a tunable wide-bandgap and a bottom cell based on a commercially established narrow-bandgap absorber technology made of cadmium telluride (CdTe).

Perovskite-cadmium telluride tandem solar cells are relatively unexplored compared to other tandems. While the efficiency potential of CdTe-based tandems is lower than CIGS-based tandems due to the higher bandgap of the CdTe bottom cell, the broader commercial success of CdTe solar cells makes them interesting to investigate for thin-film tandem applications.

It was reported that about a week ago, Kunshan GCL Optoelectronic Material launched the first phase of a photovoltaic energy storage equipment production project was launched, backed by a total investment of Yuan 570 million (over USD$80 million).

The project is undertaken by Kunshan High-Tech Group, which is responsible for the customized construction of a high standard factory area for the 1 GW production project of perovskite photovoltaic modules for enterprises. 

As part of the Investing in America agenda, the U.S. Department of Energy (DOE) recently announced a $71 million investment in research, development, and demonstration projects to grow the network of domestic manufacturers across the U.S. solar energy supply chain. 

The selected projects will address gaps in the domestic solar manufacturing capacity for supply chain including equipment, silicon ingots and wafers, and both silicon and thin-film solar cell manufacturing. The projects will also open new markets for solar technologies such as dual-use photovoltaic (PV) applications, including building-integrated PV and agrivoltaics. 

Small-molecule ionic liquids are frequently used as efficient bulk phase modifiers for perovskite materials. However, their inherent characteristics, such as high volatility and ion migration, pose challenges in addressing the stability issues associated with perovskite solar cells (PSCs). Recently, researchers at China's Northwestern Polytechnical University and CNPC Tubular Goods Research Institute designed improved poly ionic liquids (ILs) with multiple active sites as efficient additives for perovskite materials.

The team's recent work shows how additive engineering with a polymerized ionic liquid to the metal halide perovskite material can improve the solar cell's function, helping to pave the way for the adoption of perovskite solar cells.

Researchers from EPFL, CSEM and Empa have demonstrated a cell design combining additive and substrate engineering that yields consistently high power conversion efficiencies and discussed various design aspects that are important for reproducibility and performance. 

The team presented two key developments with a synergetic effect that boost the PCEs of tandem devices with front-side flat Si wafers—the use of 2,3,4,5,6-pentafluorobenzylphosphonic acid (pFBPA) in the perovskite precursor ink that suppresses recombination near the perovskite/C60 interface and the use of SiO₂ nanoparticles under the perovskite film that suppress the enhanced number of pinholes and shunts introduced by pFBPA, while also allowing reliable use of Me-4PACz as a hole transport layer. 

Researchers at China's Shanghai University of Electric Power have used dibenzoylmethane (DBM) as a precursor additive introduced in order to regulate the crystallization of CsPbI₂Br perovskite while passivating its associated defects. 

Inorganic CsPbI₂Br perovskite solar cells (PSCs) have attracted massive interest but the tendency towards unruly crystallization and poor film quality of inorganic CsPbI₂Br perovskites are major factors limiting their performance improvement. In their recent work, the scientists used DBM additive engineering for efficient and stable carbon-based CsPbI₂Br PSCs.

Researchers from India's Chiktara University have reported improved stability and performance of organic-inorganic perovskite solar cells by applying a strategy called bandgap grading.

The method is based on enabling the cell perovskite absorber to collect a wider range of light photons by modifying its thickness and characteristics. The team explains that its recent study demonstrates the effectiveness of both linear and parabolic bandgap grading strategies in optimizing light absorption and boosting performance, showing its potential. 

Israel-based SOLRA-PV showcases its cutting-edge indoor perovskite solar panel technology in action by successfully powering an entire IoT device setup. The system comprises an indoor panel, an environmental sensor, Bluetooth, and power management.

As you can see in the video, the prototype device performs a measurement every 10 minutes and transmits it to the smartphone. Utilizing SOLRA-PV's panels effectively captures indoor light for power generation, thus paving the way for the development of battery-free devices. The Company states that under indoor light conditions of 1000 lux, the panel produces 0.5 mW of power.

Researchers from King Abdullah University of Science and Technology (KAUST), Kaunas University of Technology and Helmholtz-Zentrum Berlin (HZB) recently improved on a previous development of record-breaking solar cells a few years ago, by expanding their invention: the self-assembled monolayers (SAMs) can now be applied not only in inverted but also in regular structure perovskite solar cells.

Self-assembling molecules arrange themselves into a single-molecule-thick layer and in this case, they act as an electron-transporting layer in solar cells.

It was reported that the Japanese government estimates the need for electricity output to rise 35% to 50% by 2050 due to growing demand from semiconductor plants and data centers backing artificial intelligence (AI). 

It was mentioned that the country is counting on perovskite solar cells, floating offshore wind farms, restarts of nuclear power plants and the introduction of next-generation reactors to meet the demand.