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   https://doi.org/10.1109/MEMS64181.2026.11419275  

   Di, Alexander; Pedowitz, Michael; Chien, Jun-Chau (January 2026, IEEE)
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   https://doi.org/10.1109/MEMS49605.2023.10052605  

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3. Measurement of three-photon excitation cross-sections of fluorescein from 1154 nm to 1500 nm

   https://doi.org/10.1364/BOE.498214  

   LaViolette, Aaron K.; Ouzounov, Dimitre G.; Xu, Chris (January 2023, Biomedical Optics Express)

   Measurements of three-photon action cross-sections for fluorescein (dissolved in water, pH ∼11.5) are presented in the excitation wavelength range from 1154 to 1500 nm in ∼50 nm steps. The excitation source is a femtosecond wavelength tunable non-collinear optical parametric amplifier, which has been spectrally filtered with 50 nm full width at half maximum band pass filters. Cube-law power dependance is confirmed at the measurement wavelengths. The three-photon excitation spectrum is found to differ from both the one- and two-photon excitation spectra. The three-photon action cross-section at 1154 nm is more than an order of magnitude larger than those at 1450 and 1500 nm (approximately three times the wavelength of the one-photon excitation peak), which possibly indicates the presence of resonance enhancement. 

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4. Photonic bandgap microcombs at 1064 nm

   https://doi.org/10.1063/5.0191602  

   Spektor, Grisha; Zang, Jizhao; Dan, Atasi; Briles, Travis C; Brodnik, Grant M; Liu, Haixin; Black, Jennifer A; Carlson, David R; Papp, Scott B (February 2024, APL Photonics)

   Microresonator frequency combs and their design versatility have revolutionized research areas from data communication to exoplanet searches. While microcombs in the 1550 nm band are well documented, there is interest in using microcombs in other bands. Here, we demonstrate the formation and spectral control of normal-dispersion dark soliton microcombs at 1064 nm. We generate 200 GHz repetition rate microcombs by inducing a photonic bandgap of the microresonator mode for the pump laser with a photonic crystal. We perform the experiments with normal-dispersion microresonators made from Ta2O5 and explore unique soliton pulse shapes and operating behaviors. By adjusting the resonator dispersion through its nanostructured geometry, we demonstrate control over the spectral bandwidth of these combs, and we employ numerical modeling to understand their existence range. Our results highlight how photonic design enables microcomb spectra tailoring across wide wavelength ranges, offering potential in bioimaging, spectroscopy, and photonic-atomic quantum technologies. 

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5. Organic NIR Photodetectors: Pushing Photodiodes Beyond 1000 nm

   https://doi.org/10.21127/yaoyigc20200039  

   Rasmussen, Seth C.; Gilman, Spencer J.; Culver, Evan W.; Wilcox, Wyatt D. (June 2021, General chemistry)

   null (Ed.)

   Advances in the synthesis of low bandgap (Eg < 1.5 eV) conjugated polymers has produced organic materials capable of absorbing near-infrared (NIR) light (800—2500 nm), with these materials first applied to photodiode NIR detectors in 2007 as an alternative to more traditional inorganic devices. Although the development of organic NIR photodetectors has continued to advance, their ability to effectively detect wavelengths in the low-energy portion of the NIR spectrum is still limited. Efforts to date concerning the production of photodiode-based devices capable of detecting light beyond 1000 nm are reviewed. 

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