Advanced fibre designs for high power laser beam delivery and generation

2009 High Power Diode Lasers and Systems Conference Pub Date : 2009-10-01 DOI:10.1109/HPD.2009.5365593

J. Hayes, Marco N. Petrovich, F. Poletti, S. Dasgupta, Xian Feng, W. Loh, N. Broderick, K. Chen, S. Alam, D. Lin, A. Malinowski, D. Richardson

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Abstract

Microstructured optical fiber (MOF) technology provides a powerful means to develop fibers with unique and enabling properties with potential uses spanning a very wide range of applications. Microstructuring of the fiber material allows access to properties unobtainable in the bulk. These include (a) the possibility to guide light in air (through photonic band-gap or low density of state effects) including spectral regions where the bulk is opaque; (b) single mode guidance over extended spectral ranges (referred to as endlessly single mode (ESM) guidance); (c) extended control of dispersion and (d) the fabrication of fibers with very much larger values of Numerical Aperture (NA) than possible using conventional fiber fabrication approaches. Furthermore these unique properties may be tailored to enhance wavelength generation in fibers through non-linear effects or in fibers containing rare-earth dopants. In the following sections we discuss recent progress in the design and fabrication of such fibers that exploit several of these opportunities.

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用于高功率激光束传输和产生的先进光纤设计

微结构光纤(MOF)技术为开发具有独特性能和潜在用途的光纤提供了强有力的手段。纤维材料的微结构允许获得在散装材料中无法获得的特性。这些包括(a)在空气中引导光的可能性(通过光子带隙或低密度状态效应)，包括主体不透明的光谱区域;(b)扩展光谱范围的单模制导(称为无穷单模(ESM)制导);(c)扩展了对色散的控制;(d)与传统的光纤制造方法相比，可以制造出数值孔径(NA)值大得多的光纤。此外，这些独特的特性可以通过非线性效应或含有稀土掺杂剂的光纤来增强光纤中的波长产生。在接下来的章节中，我们将讨论利用这些机会设计和制造这种纤维的最新进展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2009 High Power Diode Lasers and Systems Conference

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