Publications by authors named "Hua-Yu Feng"
In this paper, we presented a novel double-layer light-trapping structure consisting of nanopores and nanograting positioned on both the surface and bottom of a gallium oxide-based solar-blind photodetector. Utilizing the finite element method (FEM), we thoroughly investigated the light absorption enhancement capabilities of this innovative design. The simulation results show that the double-layer nanostructure effectively combines the light absorption advantages of nanopores and nanogratings.
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- Three-dimensional magnetoplasmonic nanostructures offer improved optical and magneto-optical properties compared to flat structures, presenting new opportunities in photonic devices.
- Traditional fabrication methods struggle with creating these complex 3D structures, but this research successfully utilizes focused ion beam (FIB) technology to build substrate-free Au/Co/Au configurations.
- The study reveals that these designs can effectively manipulate the Faraday effect, enhancing the local magnetic field and allowing for tunable properties, which greatly expands the potential for innovative magneto-optical devices.
Article Synopsis
- Square nanopore arrays were created on β-GaO microflakes using focused ion beam (FIB) etching to fabricate solar-blind photodetectors (PDs).
- The transformation from a gate voltage depletion mode to an oxygen depletion mode was achieved through FIB etching, enhancing the device's performance.
- The resulting photodetectors showcased impressive metrics, including high responsivity, detectivity, and light-to-dark ratio, while also being stable and reproducible, indicating a promising method for developing advanced PDs.
The mild reaction of the preorganized silsesquioxane precursor with Mn(II) acetate under ambient conditions results in a mixed-valent {MnMn} nanocage () which is protected by both acyclic trimer [Si3] and cyclic tetramer [Si4]. Serendipitous capture of atmospheric CO as a μ-carbonate anion placed at the center supports the formation of the cluster. The magnetic analysis reveals the strong antiferromagnetic interactions between Mn ions.
View Article and Find Full Text PDFWe present a systematic study to separate the different contributions to the dichroic response of complex plasmonic split-ring/ring magneto-chiral systems. For this, we first construct metastructures with plasmonic, chiral and magneto-optical functionalities by specific arrangements of different building blocks, each of them responsible for one of the functionalities. Then, by the use of Mueller matrices in forward/backward spectroscopic measurements under magnetic field, we separate optical anisotropy from pure chiral contributions to the overall dichroic response of the system.
View Article and Find Full Text PDFHere we present a novel active system, which combines the plasmon resonance enhancement of the magneto-optical activity in magnetoplasmonic nanostructures and the strong electromagnetic field localization of split ring resonators. The structures consist of a gold split ring resonator placed on top of a gold nanoring in the section of which a Co nanodot is inserted. By placing the split ring gap on top of the nanodot, and continuously varying the split ring gap opening, we are able to tune and enhance the electromagnetic field intensity in the Co nanodot, as confirmed experimentally by EELS and numerically using DDA simulation methods.
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