Most of the “technologies of the future” that we’ve been seeing become highly studied and incredibly in-demand are those intended to enhance efficiencies and improve upon the availability and usage of energy, time, and money. These are among the chief reasons 3D printing has captured the limelight in fabrication–and that, on the energy side of the spectrum, solar power is being ever more embraced. We’ve seen the two brought together in applications as diverse as health care, motors, and space stations, all broadly with the goal of using additive manufacturing techniques to create low-cost, high-power solar capturing devices.
A new paper out of the Netherlands, published recently under a Creative Commons License, takes a strong scientific look at 3D printing to enhance the performance of solar cells by creating a light trap. Progress toward this end could create environmentally-friendly sources of energy, harvesting power from the sunlight through a 3D printed light concentrator to enhance the efficiency of solar capturing devices.
The paper, 3D-printed concentrator arrays for external light trapping on thin film solar cells, was authored by Lourens van Dijk, E.A. Pepijn Marcus, A. Jolt Oostra, Ruud E.I. Schropp, and Marcel Di Vece.
This particular study focuses primarily on efficiency, in that by optimal design and 3D printed light traps, the solar cells are able to trap the light in such a way that its energy is able to be concentrated and power conversion conducted at superior levels. As noted in the document, the study’s highlights include:
- We successfully 3D-printed a universally applicable external light trap.
- We demonstrated an improvement of the EQE of an organic solar cell up to 62%.
- The external light trap is made of a scalable array of concentrators.
- Our model demonstrates potential for more enhancement by external light trapping.
- A detailed technical pathway for further optimization is presented.
The most important part of the paper is in that first bullet point: successfully. By having already created on a small scale a functional system, they are now able to proceed to the next step, which is scaling up to larger solar panel systems.
“An external light trap consists of a parabolic concentrator and a spacer that redirects the photons that are reflected by the solar cell back towards the solar cell,” they write. “These retro-reflections enable higher absorptance and improved power conversion efficiency. … The 3D-printed traps were placed on top of an organic solar cell which resulted in a significant enhancement of the external quantum efficiency…”
In their process, the team examined the use of an external–rather than the currently more often deployed internal–method of light trapping for thin solar cells, which perform optimally in array settings, based on parabolic design and created using . The external, 3D printed light trap has further benefits in that it is an add-on to a solar cell, thus adding to, rather than recreating, the proverbial wheel.
The team followed up with the conclusion that:
“We demonstrated that external light trapping is of interest for all solar cells as its effectiveness does not depend on the refractive index or texture of the solar cell and it is easy to apply. As the device is an add-on it guarantees that there is no negative impact on the electrical properties of the solar cell. … The use of 3D-printed light traps with a square, hexagonal and circular parabolic concentrators resulted in a significantly improved EQE of an organic solar cell.”
