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Piezoelectrically actuated high-speed spatial light modulator for visible to near-infrared wavelengths

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arxiv 2410.19058 v1 pith:46JFYFVP submitted 2024-10-24 physics.optics physics.app-ph

Piezoelectrically actuated high-speed spatial light modulator for visible to near-infrared wavelengths

classification physics.optics physics.app-ph
keywords modulatortechnologyhighrequirementsactuateddesignextinctionhigh-speed
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Advancements in light modulator technology have been driving discoveries and progress across various fields. The problem of large-scale coherent optical control of atomic quantum systems-including cold atoms, ions, and solid-state color centers-presents among the most stringent requirements. This motivates a new generation of high-speed large-scale modulator technology with the following requirements: (R1) operation at a design wavelength of choice in the visible (VIS) to near-infrared (NIR) spectrum, (R2) a scalable technology with a high channel density (> 100mm-2 ), (R3) a high modulation speed (> 100MHz), and (R4) a high extinction ratio (> 20 dB). To fulfill these requirements, we introduce a modulator technology based on piezoelectrically actuated silicon nitride resonant waveguide gratings fabricated on 200mm diameter silicon wafers with CMOS compatible processes. We present a proof-of-concept device with 4 x 4 individually addressable 50 {mu}m x 50 {mu}m pixels or channels, each containing a resonant waveguide grating with a ~ 780 nm design wavelength, supporting > 100MHz modulation speeds, and a spectral response with > 20 dB extinction.

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