“Existing 3D printers produce rough 3D structures that aren’t optically uniform and thus can’t be used for high-performance optics,” said research team leader Prof. Tal Carmon from the School of Electrical Engineering, Fleischman Faculty of Engineering, at Tel Aviv University in Israel. “Mimicking the way a pinecone’s scales bend outward to release seeds, our laser-induced technique triggers precise bending in ultra-thin glass sheets and can be used to create highly transparent, ultra-smooth 3D microphotonic devices for a variety of applications.”
In Optica, Optica Publishing Group’s journal for high-impact research, the researchers reported that the new laser-induced folding method can create 3-mm-long structures just 0.5 microns thick — about 1/200th the width of a human hair — setting a record length-to-thickness ratio of 3D structures. They also created helix shapes as well as concave and convex mirrors with surfaces so smooth — less than a nanometer of variation — that light reflects off them without distortion.
“Similar to how large 3D printers can fabricate almost any household item, photonic origami could enable a variety of tiny optical devices,” said Carmon. “For example, it can be used to generate micro-zoom lenses that could replace the five separate cameras used in most smartphones or to fabricate microphotonic components that use light instead of electricity — helping drive the shift toward faster, more efficient alternatives to traditional electronics in our computers.”
Structures made with photonic origami
Folded by accident
The new method was discovered by chance when Carmon asked graduate student Manya Malhotra to pinpoint where an invisible laser was hitting the glass by increasing the power until the spot glowed. Instead of glowing, the glass folded — revealing a simple and unexpected way to achieve glass folding. Malhotra then became the pioneering expert in photonic origami.
The glass folds because, as one side is heated with a laser, the glass liquifies and surface tension becomes stronger than gravity. As the surface tension increases, the glass is pulled into a fold precisely where the laser hits.
To apply this discovery, lab engineer Ronen Ben Daniel fabricated a thin layer of silica glass on a silicon chip and then shaped it into the required two-dimensional form. Before bending the glass, the researchers used etching to undercut the silicon beneath the glass sheet while leaving a small support region to hold it in place. Using CO2 laser pulses, they showed that thin glass sheets on a silicon chip could be folded in less than a millisecond, with a speed of 2 m/s and acceleration exceeding 2000 m/s2.
“It was exciting to see the folding silica under the microscope,” said Carmon. “The level of control we had over 3D microphotonic architecture came as a pleasant surprise — especially given that it was achieved with a simple setup involving just a single laser beam focused on the desired fold.”
Folding glass bar
Creating microscopic structures
Using the new photonic origami approach, the researchers were able to bend sheets of glass up to 10 microns thick into shapes ranging from a 90-degree knee to helices. They were able to do this with fine control, down to 0.1 microradians.
They also used the new approach to create an extremely lightweight and precise table structure containing a concave cavity mirror, a type of mirror that focuses light. This structure was inspired by a theoretical paper by P.K. Lam from the Australian National University that proposed exploring potential deviations from Newtonian gravity at very small scales using optically levitated cavity mirrors that might be possible to fabricate using photonic origami.
To make the tiny table light enough, the researchers began with a glass sheet just 1/20 the thickness of a human hair (5 microns). They patterned the sheet much like a child’s foldable paper table toy and used their photonic origami technique to fold it into a 3D table after fabricating a concave mirror at the base of the table.
According to the researchers, this ultra-light, compact table could, in principle, be optically levitated and used to explore possible deviations from Newtonian gravity. These types of experiments could provide insights into astronomical mysteries associated with dark matter —the only area in physics where experimental observations consistently defy current theoretical predictions.
“High-performance, 3D microphotonics had not been previously demonstrated,” said Carmon. “This new technique brings silica photonics — using glass to guide and control light — into the third dimension, opening up entirely new possibilities for high-performance, integrated optical devices.”
About Optica
Optica is an open-access journal dedicated to the rapid dissemination of high-impact peer-reviewed research across the entire spectrum of optics and photonics. Published monthly by Optica Publishing Group, the Journal provides a forum for pioneering research to be swiftly accessed by the international community, whether that research is theoretical or experimental, fundamental or applied. Optica maintains a distinguished editorial board of more than 60 associate editors from around the world and is overseen by Editor-in-Chief Prem Kumar, Northwestern University, USA. For more information, visit Optica.
About Optica Publishing Group
Optica Publishing Group is a division of the society, Optica, Advancing Optics and Photonics Worldwide. It publishes the largest collection of peer-reviewed and most-cited content in optics and photonics, including 18 prestigious journals, the society’s flagship member magazine, and papers and videos from more than 835 conferences. With over 400,000 journal articles, conference papers and videos to search, discover and access, our publications portfolio represents the full range of research in the field from around the globe.
