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Microlenses, although used in a number of applications including smart phones to boost performances, are an expensive and time taking alternative for mass commercial uses. But now, a newly developed technology, called laser catapulting, could make it easier and less expensive to fabricate these miniaturized lenses with customized properties, such as shape or focusing power.
Researchers from Istituto Italiano di Tecnologia in Italy described their new laser-additive method for creating microlenses using a single laser pulse in The Optical Society (OSA) journal Optical Materials Express. The technology even allows microlenses and microlens arrays to be fabricated directly on cameras or solar cells.
Microlenses improve the performance of cameras and solar cells by concentrating light into the most sensitive areas of the devices. For example, they are widely used in the newest smartphone cameras to increase sensitivity and imaging speed in low-light conditions. The fabrication approach of the researchers, simplifies the production of lenses while allowing more variety in the design and more flexibility in the environments where microlenses can be used. According to research team leader Martí Duocastella, in addition to completely new applications, this method could lead to new cameras that acquire video under low light conditions, solar cells with improved efficiency and microscopes that are better at capturing fast processes.
Catapulting with Light
Although micro-optics is commercially available, they can be prohibitively expensive and hard to add to existing devices. Even with traditional microlens fabrication methods such as photolithography, it is difficult to integrate lenses or to make very densely packed microlens arrays. The researchers developed catapulting to overcome these limitations.
The method uses a laser pulse to remove and catapult a micro disk from a thin polymeric film and drop it onto a defined region of interest. The polymer in the micro disk is then heated so it can thermally reflow, allowing capillary forces — the same ones that make water droplets spherical — to shape the micro-disk into a round lens. Changing the shape of the laser beam allows fabrication of microlenses with different focusing properties or shapes, such as rectangular, triangular or circular. According to Duocastella, Laser catapulting connects the dots between existing laser-based fabrication methods to solve problems with current microlens fabrication strategies. It fills the gap between the growing number of applications that require microlenses and the technologies capable of generating on-demand customized micro-optics.
After studying the relationship between the laser beam shape and the resulting micro-disks, the researchers explored the reproducibility, precision and accuracy of their technique. Their analysis showed that the method could be used to reproducibly produce microlenses with radiuses between 50 and 250 microns and very high smoothness. Measuring the optical properties of the microlenses and the light collection capabilities of microlens arrays made with the technique showed that these micro-optics exhibited diffraction-limited performance, meaning that they were as good as theory allows. The researchers say that laser catapulting could be combined with fast laser beam shaping methods for on-the-fly control of optical performance and shape of individual microlenses within an array.
Capturing Fast Biological Processes
The researchers plan to use laser catapulting to fabricate microlenses on top of photodetector arrays so they can develop a high-speed 3D microscopy system to characterize very fast biological processes, such as neuronal communications or virus trafficking. The microlenses will increase the light-collecting efficiency of the photodetectors and thus decrease imaging time. These novel photodetector arrays offer important advantages compared to confocal microscopy but can’t collect as much light as traditional single point detectors. The researchers believe that microlenses, and laser catapulting in particular, will help improve the performance of these photodetector arrays and expand their use among the microscopy community.
Click here to read the published paper.
Click here to view the video showing the images seen in the direct-writing system as a polymeric film is irradiated with a laser.