Finding the ideal size for a quantum dot


From pv magazine Global

Quantum dots, crystal structures measuring just a few nanometers, are widely investigated for their potential to boost solar cell efficiencies by acting as a “light sensitizer” capable of absorbing and transferring light to another molecule. The process is known as “light fusion” and it enables an existing solar cell to absorb parts of the light spectrum with energy lower than its bandgap.

Most of the achievements made with quantum dots to date have been in conjunction with perovskite or organic PV semiconductors. Researchers have struggled to tune quantum dots to absorb the right wavelengths of light–and infra-red light in particular–to be compatible with silicon solar cells.

New research from Australia’s Centre for Excellence in Exciton Science, reports on an algorithm that can calculate the ideal characteristics for a quantum dot to maximize cell efficiency. Researchers used the algorithm to calculate that lead-sulfide quantum dots could set a new quantum dot cell efficiency record and ensure compatibility with silicon.

Details of the work are found in the paper Optimal quantum dot size for photovoltaics with fusion, published in Nanoscale.

More than size

The researchers found that size is a vital factor in the quantum dot’s performance, and that bigger does not always mean better.

“This whole thing requires understanding of the sun, the atmosphere, the solar cell and the quantum dot,” said Monash University’s Laszlo Frazer who worked on the paper. He compares the design of optimal quantum dots for particular light and solar cell conditions to the tuning of a musical instrument to a certain pitch.

Having worked to optimize the quantum dot’s ability to capture light more effectively, the next step for the researchers will be to look at the process where the dot transfers this light energy to an emitter.

“This work tells us a lot about the capturing of light,” Laszlo said. “Releasing it again is something that needs a lot of improvement. There’s definitely a need for multidisciplinary contributions here.”

The group also hopes to start building and testing prototype solar cells complete with quantum dot technology in order to better understand the performance and application of their theory.

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