Next-generation optics in just two minutes of cooking time
- Date:
- February 11, 2019
- Source:
- Ecole Polytechnique Fédérale de Lausanne
- Summary:
- One of the key building blocks of flexible photonic circuits and ultra-thin optics are metasurfaces. And engineers have now discovered a simple way of making these surfaces in just a few minutes -- without needing a clean room -- using a method already employed in manufacturing.
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Optical circuits are set to revolutionize the performance of many devices. Not only are they 10-100 times faster than electronic circuits, but they also consume a lot less power. Within these circuits, light waves are controlled by extremely thin surfaces called metasurfaces that concentrate the waves and guide them as needed. The metasurfaces contain regularly spaced nanoparticles that can modulate electromagnetic waves over sub-micrometer wavelength scales.
Metasurfaces could enable engineers to make flexible photonic circuits and ultra-thin optics for a host of applications, ranging from flexible tablet computers to solar panels with enhanced light-absorption characteristics. They could also be used to create flexible sensors to be placed directly on a patient's skin, for example, in order to measure things like pulse and blood pressure or to detect specific chemical compounds.
The catch is that creating metasurfaces using the conventional method, lithography, is a fastidious, several-hour-long process that must be done in a clean room. But EPFL engineers from the Laboratory of Photonic Materials and Fiber Devices (FIMAP) have now developed a simple method for making them in just a few minutes at low temperatures -- or sometimes even at room temperature -- with no need for a clean room. The EPFL's School of Engineering method produces dielectric glass metasurfaces that can be either rigid or flexible. The results of their research appear in Nature Nanotechnology.
Turning a weakness into a strength
The new method employs a natural process already used in fluid mechanics: dewetting. This occurs when a thin film of material is deposited on a substrate and then heated. The heat causes the film to retract and break apart into tiny nanoparticles. "Dewetting is seen as a problem in manufacturing -- but we decided to use it to our advantage," says Fabien Sorin, the study's lead author and the head of FIMAP.
With their method, the engineers were able to create dielectric glass metasurfaces -- rather than metallic metasurfaces -- for the first time. The advantage of dielectric metasurfaces is that they absorb very little light and have a high refractive index, making it possible to effectively modulate the light that propagates through them.
To construct these metasurfaces, the engineers first created a substrate textured with the desired architecture. Then they deposited a material -- in this case, chalcogenide glass -- in thin films just tens of nanometers thick. The substrate was subsequently heated for a couple of minutes until the glass became more fluid and nanoparticles began to form in the sizes and positions dictated by the substrate's texture.
The engineers' method is so efficient that it can produce highly sophisticated metasurfaces with several levels of nanoparticles or with arrays of nanoparticles spaced 10 nm apart. That makes the metasurfaces highly sensitive to changes in ambient conditions -- such as to detect the presence of even very low concentrations of bioparticles. "This is the first time dewetting has been used to create glass metasurfaces. The advantage is that our metasurfaces are smooth and regular, and can be easily produced on large surfaces and flexible substrates," says Sorin.
Story Source:
Materials provided by Ecole Polytechnique Fédérale de Lausanne. Note: Content may be edited for style and length.
Journal Reference:
- Tapajyoti Das Gupta, Louis Martin-Monier, Wei Yan, Arthur Le Bris, Tùng Nguyen-Dang, Alexis Gérald Page, Kuan-Ting Ho, Filiz Yesilköy, Hatice Altug, Yunpeng Qu, Fabien Sorin. Self-assembly of nanostructured glass metasurfaces via templated fluid instabilities. Nature Nanotechnology, 2019; DOI: 10.1038/s41565-019-0362-9
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