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Abstract
Chip-scale chemical detections were demonstrated by mid-Infrared (mid-IR) integrated optics made by aluminum nitride (AlN) waveguides on flexible borosilicate templates. The AlN film was deposited using sputtering at room temperature, and it exhibited a broad infrared transmittance up to λ = 9 µm. The AlN waveguide profile was created by microelectronic fabrication processes. The sensor is bendable because it has a thickness less than 30 µm that significantly decreases the strain. A bright fundamental mode was obtained at λ = 2.50–2.65 µm without mode distortion or scattering observed. By spectrum scanning at the -OH absorption band, the waveguide sensor was able to identify different hydroxyl compounds, such as water, methanol, and ethanol, and the concentrations of their mixtures. Real-time methanol monitoring was achieved by reading the intensity change of the waveguide mode at λ = 2.65 μm, which overlap with the stretch absorption of the hydroxyl bond. Due to the advantages of mechanical flexibility and broad mid-IR transparency, the AlN chemical sensor will enable microphotonic devices for wearables and remote biomedical and environmental detection.
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Details
1 Texas A&M University, Department of Electrical and Computer Engineering, College Station, United States (GRID:grid.264756.4) (ISNI:0000 0004 4687 2082); Texas A&M University, Department of Materials Science and Engineering, College Station, United States (GRID:grid.264756.4) (ISNI:0000 0004 4687 2082); Texas A&M University, Center for Remote Health Technologies and Systems, College Station, United States (GRID:grid.264756.4) (ISNI:0000 0004 4687 2082)
2 Harvard University, Center for Nanoscale Systems, Cambridge, United States (GRID:grid.38142.3c) (ISNI:000000041936754X)
3 J. A. Woollam Co., Inc., Lincoln, USA (GRID:grid.38142.3c)