A solar redox flow cell (SRFC). Image: University of Porto

Scientists in China evaluated the prospects for various approaches to integrating both solar generation and energy storage in a single device. Their work outlines several ways this could increase the efficiency of solar energy storage, and recommends that future research on this area should focus on integration of materials with the highest specific capacity for energy storage, alongside the dual function of solar energy harvesting.

From pv magazine

Maximizing the efficiency of energy storage, to make good use of every electron generated from intermittent renewables, will be an ongoing challenge for scientists over the coming decades, and one that will likely see a whole host of new technologies and materials introduced to increasingly specialized markets.

Among the less explored approaches here is single-device integrated solar generation and energy storage, or solar-powered redox batteries (SPRBs). These promise to eliminate much of the additional power electronics and other equipment needed to shuttle energy from a PV system to a battery, meaning both cheaper and more efficient energy storage. So far, a few different approaches to fabricating such a device have emerged, and while progress has been made, none has yet achieved the type of performance that would bring interest from commercial developers.

Scientists led by China’s Nanjing University of Information Science and Technology conducted an extensive review of recent progress with SPRBs, focusing on the development of high-performance dye sensitizer materials, the photoelectrochemical performance of different electrode materials, and the mechanism and structure of such devices. Their review and recommendations can be found in the paper Integrated Photovoltaic Charging and Energy Storage Systems: Mechanism, Optimization, and Future, published in Small.

The paper notes that dye sensitizer materials and semiconductor photocatalysts have shown the most promising results so far, and recommend a range of strategies focused on enhanced light absorption, charge separation, energy matching and overall device optimization. It also states that working with materials that exhibit a high specific capacity for energy storage will be key in developing commercially relevant types. If this potential can be realized, the review finds multiple applications including capacitors, solid-state batteries, microdevices, and smart wearables that could all benefit from such integrated technology.

Author: MARK HUTCHINS