We developed a liquid-crystal spatial light modulator having a 30 mm active area and a multilayered dielectric mirror for industrial infrared lasers to establish an innovative manufacturing and fabrication technique in the smart-manufacturing post-pandemic era. The reconstruction of computer-generated holograms was achieved to demonstrate the concept of this device in the IR region. The incident phase performance characteristics of this device under high-power laser irradiation were obtained using a 1030 nm ultrashort pulse laser. The work presented here will accelerate the use of liquid-crystal SLMs in high-precision laser processing of the process-resistant materials and high-throughput processing for additive manufacturing.
We attempted to observe deep regions in biological samples through two-photon excitation microscopy adopting a spatial light modulator (SLM). The SLM is used for correcting spherical aberration (SA) caused by the refractive-index mismatch between the immersion medium and sample. In the observation of fluorescent beads in transparent epoxy resin, the fluorescence intensity from a scan with SA correction was 50 times that from a scan without SA correction. After that, we observed blood vessels in a mouse brain, which became transparent with a clearing agent.
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