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Fig. 4 Guided-wave propagation in a single-crystalline KDP hexagonal microstructure. Guided-wave propagation in a single-crystalline KDP hexagonal microstructure.

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Presentation on theme: "Fig. 4 Guided-wave propagation in a single-crystalline KDP hexagonal microstructure. Guided-wave propagation in a single-crystalline KDP hexagonal microstructure."— Presentation transcript:

1 Fig. 4 Guided-wave propagation in a single-crystalline KDP hexagonal microstructure.
Guided-wave propagation in a single-crystalline KDP hexagonal microstructure. (A and B) SHG intensity distribution across the exit facet of (A) a hollow-core microtube (nominal diameter, 15 μm; wall thickness, 3 μm) and (B) a solid-core microrod (nominal diameter, 25 μm). Note that the SHG light fills the entire solid core, indicating a transversely confined bulk SHG effect. Typically, the yield of solid-core structures is a factor of three to five times higher SHG than that of the hollow-core structures. (C) Very weak 532-nm light is transversely focused on the left end of a microstructure. (D) CCD image captured above the sample showing no leakage light for a large segment of the microstructure (the small green spot in the middle is from the microstructure holder). At the right end, a bright light spot represents the light propagated through the microstructure by guided mode, vividly demonstrating efficient guided-wave propagation. Yan Ren et al. Sci Adv 2016;2:e Copyright © 2016, The Authors

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