Browsing by Author "Zhou, Jingan"
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Item Characterizations of two-photon absorption process induced by defects in aluminum nitride using Z-scan method(IOP Publishing, 2024) Zhou, Jingan; Li, Tao; Zhao, Xuan; Zhang, Xiang; Doumani, Jacques; Xu, Mingfei; He, Ziyi; Luo, Shisong; Mei, Zhaobo; Chang, Cheng; Robinson, Jacob T.; Ajayan, Pulickel M.; Kono, Junichiro; Zhao, Yuji; Smalley-Curl InstituteIn this work, we reported two-photon absorption (TPA) measurements for aluminum vacancies in Aluminum nitride single crystals. We measured the linear transmission and identified the defect levels. Using the Z-scan method, we measured the TPA coefficients of the transitions between defect levels from 380 nm to 735 nm. The transition occurs between the aluminum vacancies defect levels. Furthermore, the power dependence shows good linear fitting, confirming the TPA mechanism. These results will be helpful for the design and fabrication of ultra-low loss waveguides and integrated photonics in the ultraviolet spectral range.Item First Demonstration of beta-phase Gallium Oxide Optical Waveguide in Visible-UV Spectrum(2023-04-17) Zhou, Jingan; Zhao, YujiWe report the first demonstration of beta-phase gallium oxide (β-Ga2O3) as optical waveguides on sapphire substrates grown by metal-organic chemical vapor deposition (MOCVD). Their propagation losses in the visible spectrum were comprehensively studied via experiments and simulations of the finite difference method by varying the dimensions of the waveguides. The fabrication process of the waveguides was shown and their propagation losses were measured by collecting the top scattered optical power along the propagation direction using a charge-coupled device (CCD) camera. The minimum measured loss was 3.7 dB/mm at a wavelength of 800 nm depending on the dimensions of the waveguides. In addition, we compared the losses of waveguides with different widths, heights, wavelengths, and polarizations. It is revealed that the total propagation loss is mainly contributed by the bulk and sidewall scattering. Combined with theoretical simulations, various loss mechanisms from two-photon absorption, sidewall scattering, top surface scattering, and bulk scattering, were discussed for β-Ga2O3 waveguides, and their contributions to the total optical loss were estimated. After all these mechanism analyses on absorption and scattering, a large improvement and optimization were applied to the material quality and etching recipe, which improves the top surface and sidewall roughness respectively. This work provides valuable information for the fabrication of optical devices based on Ga2O3 material, which is promising for applications in on-chip high-speed interconnections and UV–NIR nonlinear optics.Item Gallium Oxide as Photonic Integrated Platforms in UV–Visible Spectrum(2023-12-01) Zhou, Jingan; Zhao, YujiWe report the gallium oxide (Ga2O3) as a photonic integrated platform and its nonlinear optical effects in the UV–visible spectra. The β-Ga2O3 as optical waveguides on sapphire substrates grown by metal-organic chemical vapor deposition (MOCVD). For linear properties, their propagation losses in the visible spectrum were comprehensively studied via experiments and simulations of the finite difference method by varying the dimensions of the waveguides. The fabrication process of the waveguides was shown and their propagation losses were measured by collecting the top scattered optical power along the propagation direction using a charge-coupled device (CCD) camera. The minimum measured loss was 3.7 dB/mm at a wavelength of 800 nm depending on the dimensions of the waveguides. For nonlinear properties, by focusing a pulsed laser beam onto a polished ε-Ga2O3 thin film, we collected the generated second harmonic photons with an ultra-sensitive femtowatt photodetector, obtaining effective second-order nonlinear optical susceptibility from visible to UV spectra. Two different measurement systems collecting reflected and transmitted photons were applied separately to make the result more convincing. The wavelength dependence from 790 nm to 900 nm and polarization dependence from TM mode to TE mode were measured as well. In addition, we compared the losses of waveguides with different widths, heights, wavelengths, and polarizations. It is revealed that the total propagation loss is mainly contributed by the bulk and sidewall scattering. Combined with theoretical simulations, various loss mechanisms from two-photon absorption, sidewall scattering, top surface scattering, and bulk scattering, were discussed for β-Ga2O3 waveguides, and their contributions to the total optical loss were estimated. After all these mechanism analyses on absorption and scattering, a large improvement and optimization were applied to the material quality and etching recipe, which improves the top surface and sidewall roughness respectively. This work provides valuable information for the fabrication of optical devices.Item High-surface-area corundum nanoparticles by resistive hotspot-induced phase transformation(Springer Nature, 2022) Deng, Bing; Advincula, Paul A.; Luong, Duy Xuan; Zhou, Jingan; Zhang, Boyu; Wang, Zhe; McHugh, Emily A.; Chen, Jinhang; Carter, Robert A.; Kittrell, Carter; Lou, Jun; Zhao, Yuji; Yakobson, Boris I.; Zhao, Yufeng; Tour, James M.; Smalley-Curl Institute; NanoCarbon Center; Welch Institute for Advanced MaterialsHigh-surface-area α-Al2O3 nanoparticles are used in high-strength ceramics and stable catalyst supports. The production of α-Al2O3 by phase transformation from γ-Al2O3 is hampered by a high activation energy barrier, which usually requires extended high-temperature annealing (~1500 K, > 10 h) and suffers from aggregation. Here, we report the synthesis of dehydrated α-Al2O3 nanoparticles (phase purity ~100%, particle size ~23 nm, surface area ~65 m2 g−1) by a pulsed direct current Joule heating of γ-Al2O3. The phase transformation is completed at a reduced bulk temperature and duration (~573 K, < 1 s) via an intermediate δʹ-Al2O3 phase. Numerical simulations reveal the resistive hotspot-induced local heating in the pulsed current process enables the rapid transformation. Theoretical calculations show the topotactic transition (from γ- to δʹ- to α-Al2O3) is driven by their surface energy differences. The α-Al2O3 nanoparticles are sintered to nanograined ceramics with hardness superior to commercial alumina and approaching that of sapphire.