用复合折射透镜聚焦高能X射线。

Focusing high-energy x rays by compound refractive lenses.

作者信息

Snigirev A, Kohn V, Snigireva I, Souvorov A, Lengeler B

出版信息

Appl Opt. 1998 Feb 1;37(4):653-62. doi: 10.1364/ao.37.000653.

DOI:10.1364/ao.37.000653

Abstract

Compound lenses made from low-Z materials (e.g., Be, B, C, and Al) set up as a linear array of refractive lenses are proposed for submicrometer focusing of high-energy x rays (>5 keV) in one or two dimensions. A theory of focusing based on Maxwell's equation and the Fresnel-Kirchhoff approach is presented. Compound refractive lenses were manufactured by drilling into an Al block a linear array of 200 closely spaced holes 0.5 mm in diameter for linear focusing and two crossed arrays of 100 holes each for point focusing. Focal spots of 3.7 mum and 8 mum x 18 mum were obtained at 30 keV for linear and two-dimensional lenses, respectively. Different technologies of manufacturing and possible applications of the proposed lenses are discussed.

摘要

有人提出用低原子序数材料（如铍、硼、碳和铝）制成复合透镜，并将其设置为折射透镜的线性阵列，用于对一维或二维的高能X射线（>5 keV）进行亚微米聚焦。本文提出了一种基于麦克斯韦方程和菲涅耳 - 基尔霍夫方法的聚焦理论。通过在铝块上钻出直径为0.5毫米、紧密排列的200个线性阵列孔来制造用于线性聚焦的复合折射透镜，以及通过钻出两个相互交叉、各有100个孔的阵列来制造用于点聚焦的复合折射透镜。对于线性透镜和二维透镜，分别在30 keV时获得了3.7微米和8微米×18微米的焦斑。文中还讨论了所提出透镜的不同制造技术和可能的应用。

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用复合折射透镜聚焦高能X射线。

Focusing high-energy x rays by compound refractive lenses.

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