Open AccessApproaches toward optimized laser-induced damage thresholds of dispersive compensating mirrors applying nanolaminates
Author(s) -
Mark Gyamfi,
Marco Jupé,
Thomas Willemsen,
Malte Brinkmann,
S. Schlichting,
Detlev Ristau
Publication year - 2018
Publication title -
institutional repository of leibniz universität hannover (leibniz universität hannover)
Language(s) - English
Resource type - Conference proceedings
DOI - 10.1117/12.2281126
Subject(s) - stack (abstract data type) , materials science , refractive index , dielectric , electric field , dispersion (optics) , optics , laser , interference (communication) , optoelectronics , amorphous solid , layer (electronics) , field (mathematics) , high refractive index polymer , composite material , computer science , physics , channel (broadcasting) , chemistry , mathematics , organic chemistry , quantum mechanics , pure mathematics , programming language , computer network
Ultra-short laser applications require high quality dielectric optics. The natural dispersion of light needs to be matched by dielectric components. However such dispersive components are very challenging for the deposition process and are characterized by high field intensities inside the layer stack. Such layers are expected to diminish the possible laser induced damage thresholds (LIDTs) because of their low optical gap value for suitable high refractive index materials. This paper reports about the manufacturing of amorphous nanolaminates to tune the optical gap. Such sequences are substituted into a conventional high reflective mirror to decrease the electric field of binary Tantala layers by 30 % which correlates to an improvement in LIDT of almost 16%.
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