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Hot Holes: In Situ Visualization of Localized Surface Plasmon Resonance‐Driven Hot Hole Flux (Adv. Sci. 20/2020)
Advanced Science ( IF 15.1 ) Pub Date : 2020-10-22 , DOI: 10.1002/advs.202070114 Hyunhwa Lee , Kyoungjae Song , Moonsang Lee , Jeong Young Park
Advanced Science ( IF 15.1 ) Pub Date : 2020-10-22 , DOI: 10.1002/advs.202070114 Hyunhwa Lee , Kyoungjae Song , Moonsang Lee , Jeong Young Park
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In article number 2001148, Moonsang Lee, Jeong Young Park, and co‐workers demonstrate that fast‐disappearing hot holes are directly visualized using photoconductive atomic force microscopy. Experimental and numerical analysis show that hot spots at the edge of plasmonic nanostructures of Au nanoprisms on p‐type GaN exhibit enhanced hot hole flux driven by surface plasmons.
中文翻译:
热孔:局部表面等离子共振驱动热孔通量的现场可视化(Adv。Sci。20/2020)
Lee Moonsang Lee,Jeong Young Park及其同事在第2001148号文章中证明,使用光电导原子力显微镜可以直接看到快速消失的热孔。实验和数值分析表明,p型GaN上Au纳米棱镜的等离子纳米结构边缘的热点显示出受表面等离激元驱动的增强的热空穴通量。
更新日期:2020-10-22
中文翻译:
热孔:局部表面等离子共振驱动热孔通量的现场可视化(Adv。Sci。20/2020)
Lee Moonsang Lee,Jeong Young Park及其同事在第2001148号文章中证明,使用光电导原子力显微镜可以直接看到快速消失的热孔。实验和数值分析表明,p型GaN上Au纳米棱镜的等离子纳米结构边缘的热点显示出受表面等离激元驱动的增强的热空穴通量。
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