Understanding nanoscale solar cells
A team of researchers from FOM Institute AMOLF and Eindhoven University of Technology have developed both a theory and an experimental method that provide the first detailed demonstration of how a nanoscale solar cell works. This had proved challenging until now due to the exceptionally small size of these solar cells. This new method has brought implementation of nanotechnology in the production of sustainable energy a step closer. The researchers published their results on 12 September 2016 in an article in Nature Nanotechnology.
Nanoscale solar cells
Until now, little was known about the detailed working mechanisms of nanoscale solar cells. Nanoscale solar cells are subject to different laws than the solar cells on our roofs and their small size makes them hard to investigate. They are so small that using standard equipment to perform measurements is not possible. AMOLF PhD researcher Sander Mann explains: "One of the things we want to know about a solar cell is how much current it produces if you shine red or blue light on it. When researchers performed this type of measurement on nanoscale solar cells, far more current was produced than was possible according to existing solar cell theories."
Casting a large shadow
"If a structure is the size of a wavelength of light, then the light reaching that structure behaves in a completely different way," explains Mann. "We are used to light behaving like a beam of particles, but at the nanoscale it behaves as a wave." The consequence is that compared to typical solar cells, nanoscale solar cells absorb far more light than you would expect based on their dimensions and they have a shadow much bigger than their surface area. "That also explains why more current can be produced by this type of solar cell than you would expect," says Mann. In the article, the researchers formulate a theory that combines the wave-like properties of light with the existing theories about how solar cells work.
Experiments with nanoscale solar cells
The theory was then tested experimentally on a solar cell made of a single nanowire. Its surface area is so small that a postage stamp could hold almost one billion of these devices. Researchers developed a new experimental method to measure the absorption of this nanowire. "Absorption measurements on nanostructures were difficult in the past, because besides absorbing a lot of light, these structures scatter a lot of light in almost all directions," explains Mann. "Using an 'integrating sphere' that encloses the whole device, we can now detect the scattered light so that we can calculate exactly how much light the nanowire solar cell has absorbed." Based on this new information, far more can be said about the quality of the nanoscale solar cell as well as how it could be improved in the future.
Contact
Erik Garnett, FOM Institute AMOLF, +31 20 754 72 31
https://amolf.nl/research-groups/nanoscale-solar-cells
Reference
S.A. Mann, S.Z. Oener, A. Cavalli, J.E.M. Haverkort, E.P.A.M. Bakkers and E.C. Garnett, 'Quantifying losses and thermodynamic limits in nanophotonic solar cells', Nature Nanotechnology, 2016.
doi: 10.1038/nnano.2016.162