Technology and R&D

The Jaguar series, with 20.81% efficiency and 445 W of maximum output, may be a solution for installations with space constraints. The panels are based on a special cell design, which Recom describes as an evolution of the half-cut cell concept.

Scientists in the United States and India are investigating the impacts of soiling on PV installations in the Indian state of Gujarat. The group, which found that soiling losses for the state could add up to $12 million per year, is looking for low-cost ways to monitor and reduce the impacts of soiling on modules in the field.

Scientists in the United States have fabricated a working lithium-ion battery using a phosphorous-based anode. The batteries show significantly higher capacity than today’s lithium-ion tech, and could serve as a guideline for future design of high-performance anodes for Li-ion batteries.

Swiss startup Insolight has raised €4.6 million to bring its concentrating PV module technology to commercial production. The panels have a claimed efficiency of 30% and power output of 160 W. Originally conceived for rootop solar, the product is now being recommended as an interesting option for agrivoltaic projects.

A new report by the International Council on Clean Transportation provides forecasts for green hydrogen prices by 2050. The group claims to have included system costs that have been ignored in green hydrogen economy assessments thus far. Average green hydrogen prices, however, will almost be halved in the United States and Europe.

The mechanisms behind light-elevated temperature-induced degradation are still not fully understood, but it is known to cause significant performance losses for modules in the field. Scientists in China are investigating the causes of the phenomenon, and are currently focused on the surface of the materials and the interfaces between the silicon and passivation layers.

An Australian innovator has designed a secure racking system he says enables super-fast installation of solar fields, which can then be relocated as needed.

Researchers have set out to study the kinetics of lithium deposition during cycling in a battery. By changing different parameters, they’ve found that it’s fairly easy to put lithium into amorphous form, which is superior on an electromechanical level.

South Korean scientists manufactured the cell with the chemical bath deposition method, using different thiourea concentrations. For the buffer layer, they used zinc instead of cadmium sulfide. The cell is flexible and is available in seven different colors.

Scientists in the United States have developed a lithography-based process for the fabrication of single-crystal perovskites. Thin films made using this process have been integrated into a range of devices, including solar cells, and have demonstrated better stability performance than their more commonly researched polycrystalline counterparts.