News Release

Researchers fabricate tiny multi-component beam shaper directly onto optical fiber

3D laser printing approach could make it possible to replace bulky optics with inexpensive microscopic devices

Peer-Reviewed Publication

Optica

Micro-optical device

image: Researchers used 3D laser printing to fabricate a high-quality, complex polymer optical device directly on the end of an optical fiber. An scanning electron microscopy image of the device is shown. It includes both a parabolic lens for light collimation and a twisted axicon optic that twists the light. view more 

Credit: Shlomi Litman, Soreq Nuclear Research Center

WASHINGTON — Researchers have shown that 3D laser printing can be used to fabricate a high-quality, complex polymer optical device directly on the end of an optical fiber. This type of micro-optical device — which has details smaller than the diameter of a human hair — could provide an extremely compact and inexpensive way to tailor light beams for a variety of applications.

“Communication technologies, the internet and many other applications are based on optical fibers,” said research team leader Shlomi Lightman from Soreq Nuclear Research Center in Israel. “When light comes out of the fiber, large bulky optical elements are typically used to route it to the next location. Our approach minimizes both the size and cost for this process by integrating the routing process into the fiber itself.”

In the Optica Publishing Group journal Optics Letters, Lightman and colleagues describe how they fabricated the tiny multi-component beam shaper directly onto a fiber. The device turns normal laser light into a twisted Bessel beam that carries orbital angular momentum and doesn’t expand in space like typical light beams.

The researchers fabricated the entire micro-optical device in less than 5 minutes. The fiber together with the micro-optical device cost less than $100, about a tenth of what a standard microscope objective lens that performs a similar function might cost.

“The ability to create a Bessel beam directly from an optical fiber could be used for particle manipulation or fiber-integrated stimulated emission depletion (STED) microscopy, a technique that produces super-resolution images,” said Lightman. “Our fabrication method could also be used to upgrade an inexpensive lens to a higher quality smart lens by printing a smart small structure on it.”

Precision planning

To make the tiny optical devices, the researchers used a fabrication technique called 3D direct laser printing. This uses a laser beam with femtosecond pulses to create two-photon absorption in a photosensitive optical material. Only the tiny volumes where two-photon absorption occurs turn solid, providing a way to create high-resolution 3D elements.

Although this 3D direct laser printing has been used for some time, it is difficult to get the scale and alignment correct when fabricating such small optics on a fiber tip. “We were able to overcome this hurdle by performing highly accurate 2D and 3D simulations before we began the fabrication process,” said Lightman. “In addition, we had to carefully think about how to integrate the optical elements with each other and then align that with the fiber core.”  

After careful planning based on the simulations, the researchers used a commercial 3D direct laser writing system and a high optical quality photosensitive polymer to print a 110-micron-tall optical device 60 microns in diameter and 110 microns tall on the end of a single mode optical fiber. The device included both a parabolic lens for light collimation and a helical axicon lens that twists the light. This turns light exiting the fiber into a twisted Bessel beam.

High quality light propagation
To analyze the quality of the fabricated optical device, the researchers built an optical measuring system to capture the shaped beam propagating from the modified fiber. They observed very low diffraction in the beam, which means that it could be useful for applications like STED microscopy and particle manipulation.

They also found that the laser power could reach close to 10 MW/cm2 before damaging the fabricated micro-optical device. This showed that even though the device was made from polymer, which is more susceptible than glass to heat damage from high powers, it could still be used to produce relatively high laser power.

Now that the researchers have demonstrated that precise multi-element micro-optics can be created using this direct 3D laser printing method, they are experimenting with using hybrid photosensitive materials that contain a low percentage of polymer. These materials could make it possible to produce higher quality optics that also have a longer shelf life and are more resistant to high laser powers, compared to polymer materials.

Paper: S. Litman, O. Porat, G. Hurviz, R. Gvishi, “Vortex-Bessel beam generation by 3D direct printing of an integrated multi-optical element on a fiber tip,” Opt. Lett, 47, 20, 5248-5251 (2022).
DOI: https://doi.org/10.1364/OL.470924

About Optics Letters

Optics Letters offers rapid dissemination of new results in all areas of optical science with short, original, peer-reviewed communications. Optics Letters accepts papers that are noteworthy to a substantial part of the optics community. Published by Optica Publishing Group and led by Editor-in-Chief Miguel Alonso, Institut Fresnel, École Centrale de Marseille and Aix-Marseille Université, France, University of Rochester, USA. For more information, visit Optics Letters.

About Optica Publishing Group (formerly OSA)

Optica Publishing Group is a division of Optica, formerly OSA, Advancing Optics and Photonics Worldwide. It publishes the largest collection of peer-reviewed content in optics and photonics, including 18 prestigious journals, the society’s flagship member magazine, and papers from more than 835 conferences, including 6,500+ associated videos. With over 400,000 journal articles, conference papers and videos to search, discover and access, Optica Publishing Group represents the full range of research in the field from around the globe.


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