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Abstract Integrated optical sensors have garnered much interest for lab‐on‐chip applications such as chemical and biological sensing and detection. Among various ways for detection schemes, spectral analysis performed by a spectrometer has shown great promise. Typically, such spectrometry is carried out in a relatively large device, owing to the fact that spectral resolution is often dictated by large optical path length. Here, a high‐resolution compact spectrometer utilizing random scattering events in a disordered medium is demonstrated. The spectrometer is inverse designed by objective‐first method and fabricated using two‐photon polymerization technique. The compact spectrometer consists of a disordered photonic structure and an inversed‐designed mode decomposer. A spectral resolution of 0.25 nm with a bandwidth of 30 nm in the near‐infrared regime is realized from a spectrometer occupying a relatively small footprint of 30 × 12.8 µm 2 . The proposed platform has a great potential to be used as a versatile lightweight and compact spectrometer for various applications including on‐chip spectrometer and sensing.
Hadibrata et al. (Fri,) studied this question.
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