Mid-infrared light directly amplifies out-of-plane phonons in few-layer MoS2 by over 80% at room temperature with 300x lower power density than visible light, yielding 0.3 nW/sqrt(Hz) noise-equivalent power for MIR detection.
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Microfabricated 18 μm YIG waveguides with co-engineered MSSW dispersion and meander transducers deliver tunable group delays of 3.3-42.8 ns from 6-19.6 GHz at 2.5-10.1 dB insertion loss and 24-39 dB isolation, outperforming fixed acoustic delay lines.
DE-LIoT introduces a centralized visible-light architecture for joint data-energy networking in IoT, claiming hardware validation with extended node lifetimes.
citing papers explorer
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Mid-infrared Assisted THz Phonon Amplification in a 2D Semiconductor for Room Temperature Detection
Mid-infrared light directly amplifies out-of-plane phonons in few-layer MoS2 by over 80% at room temperature with 300x lower power density than visible light, yielding 0.3 nW/sqrt(Hz) noise-equivalent power for MIR detection.
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Dispersion Engineered Frequency Tunable Delay Platform based on Magnetostatic Surface Waves
Microfabricated 18 μm YIG waveguides with co-engineered MSSW dispersion and meander transducers deliver tunable group delays of 3.3-42.8 ns from 6-19.6 GHz at 2.5-10.1 dB insertion loss and 24-39 dB isolation, outperforming fixed acoustic delay lines.
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DE-LIoT: The Data-Energy Networking Paradigm for Sustainable Light-Based Internet of Things
DE-LIoT introduces a centralized visible-light architecture for joint data-energy networking in IoT, claiming hardware validation with extended node lifetimes.