Amplification of solid high harmonics in semiconductor nanostructures (Conference Presentation)

Advances in Ultrafast Condensed Phase Physics Pub Date : 2018-05-29 DOI:10.1117/12.2306896

D. Franz, R. Nicolas, W. Boutu, Liping Shi, Q. Ripault, M. Kholodtsova, B. Iwan, Ugaitz Elu Etxano, M. Kovacev, J. Biegert, H. Merdji

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引用次数: 1

Abstract

Nanoscale amplification of non-linear processes in solid-state devices opens novel applications in nano-electronics, nano-medicine or high energy conversion for example. Coupling few nano-joules laser energy at a nanometer scale for strong field physics is demonstrated. We report enhancement of high harmonic generation in nano-structured semiconductors using nanoscale amplification of a mid-infrared laser in the sample rather than using large laser amplifier systems. Field amplification is achieved through light confinement in nano-structured semiconductor 3D waveguides. The high harmonic nano-converter consists of an array of zinc-oxide nanocones. They exhibit a large amplification volume, 6 orders of magnitude larger than previously reported [1] and avoid melting observed in metallic plasmonic structures. The amplification of high harmonics is observed by coupling only 5-10 nano-joules of a 3.2 µm high repetition-rate OPCPA laser at the entrance of each nanocone. Harmonic amplification (factor 30) depends on the laser energy input, wavelength and nanocone geometry [2]. [1] Vampa et al., Nat. Phys. 13, 659–662 (2017). [2] Franz et al., arXiv:1709.09153 [physics.optics] (2017)

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半导体纳米结构中固体高次谐波的放大(会议报告)

固态器件中非线性过程的纳米级放大在纳米电子学、纳米医学或高能量转换等领域开辟了新的应用。在强场物理中，证明了在纳米尺度上耦合几纳米焦耳激光能量。我们报告了使用纳米级放大样品中的中红外激光器而不是使用大型激光放大系统来增强纳米结构半导体中的高谐波产生。通过纳米结构半导体三维波导中的光约束实现了场放大。高次谐波纳米变换器由氧化锌纳米锥阵列组成。它们表现出很大的放大体积，比先前报道的[1]大6个数量级，并且避免了在金属等离子体结构中观察到的熔化。通过在每个纳米锥的入口处耦合一个3.2 μ m高重复速率的OPCPA激光器，观察到高次谐波的放大。谐波放大(30倍)取决于激光能量输入、波长和纳米锥几何形状[2]。[1]王晓明，王晓明，王晓明，等。中国生物医学工程学报，2016,33(2):659-662。[2]李志强，陈志强，陈志强，等。光学)(2017)

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Advances in Ultrafast Condensed Phase Physics

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