Commentary

ANU breakthrough: Butterfly effect could boost solar cell efficiency

Published by

A team of Australian National University researchers has taken inspiration from the humble butterfly wing to develop a nano-technology that could greatly improve the efficiency of solar cells.

Drawing from the neotropical Morpho Didius butterfly, whose wings have tiny cone-shaped nanostructures that scatter light to create a striking blue iridescence, the ANU team was able to finely control the direction of light in a range of experiments, including tests on next generation solar cells.

OLYMPUS DIGITAL CAMERA

Dr Lal said the aim, in terms of solar, was to absorb all of the blue, green and ultraviolet colours of sunlight in the perovskite layer of a solar cell, and all of the red, orange and yellow light in the silicon layer – known as a tandem solar cell with double-decker layers.

It was with these kinds of solar cells that researchers at the ANU surpassed silicon efficiency records just last month.

“Techniques to finely control the scattering, reflection and absorption of different colours of light are being used in the next generation of very high-efficiency solar panels,” said Dr Lal from the ANU Research School of Engineering.

“Being able to make light go exactly where you want it to go has proven to be tricky up until now.

“We were surprised by how well our tiny cone-shaped structures worked to direct different colours of light where we wanted them to go,” he said.

In terms of energy efficiency and passive house and building design, Dr Lal said the technique could also be used in architecture to control how much light and heat passed through windows.

“Using our approach, a window could be designed to be transparent to some colours non-see through and matt textured for others – so there are very cool potential applications in architecture,” he said.

And while the research paper, published in ACS Photonics, flags some constraints on the technology’s performance in tandem solar cells, it notes that the technique for making the nanostructure is “very scalable” and does not require expensive technology.

“These intricate nanostructures grow and assemble themselves – it’s not by precise control with a tiny laser or electrons,” Dr Lal said.

The research paper is published with co-authors Kevin Le (pictured above), Andrew Thomson, Maureen Brauers, Tom White and Kylie Catchpole.

Sophie Vorrath

Sophie is editor of Renew Economy and editor of its sister site, One Step Off The Grid . She is the co-host of the Solar Insiders Podcast. Sophie has been writing about clean energy for more than a decade.

Recent Posts

Deed signed to boost export link from new renewable energy zone to main demand centres

Work to start on sub-station and transmission line upgrades to boost the export capacity of…

14 July 2026

Australia’s biggest vanadium flow battery planned for clean energy precinct at former coal mine

A proposed 108 megawatt (MW), eight hour vanadium flow battery - with lower fire risk…

14 July 2026

Turbines and transmission towers up and concrete foundations poured at rare state-owned wind farm

State-owned wind farm marks a "huge few weeks of milestones" including delivery of transformers, erection…

13 July 2026

One of Australia’s biggest renewables developers seeks to build one of country’s biggest new gas plants

Plans for one of the nation's biggest new gas plants join the queue for federal…

13 July 2026

Regulator bans two solar and battery installers for failing to meet standards and regulations

Regulator says two individuals banned from installing solar PV and home batteries under the SRES…

13 July 2026

Andrew Forrest’s Squadron Energy unveils another big wind project near crowded renewable zone

Squadron's latest wind project located just outside of crowded renewable zone, and will seek to…

13 July 2026