Lucas Willis scite author profile

Considerable interest centres around the use of germanium as a reflector material in high-power carbon-dioxide lasers. An important problem is the damage caused to the mirror surface as the result of the dynamic development of imperfections. This damage may be caused by an interference process which has been described previously. A characteristic of the damage which occurs is the melting of the germanium followed by resolidification. The authors describe a certain type of melting pattern which depends upon density differences between the liquid and solid phases. The experimental phenomenon is first described with reference to germanium laser mirror damage and this is followed by a theoretical model of the resolidification of molten regions where a density difference occurs between the solid and liquid phases, as in paraffin wax for example.

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UV fatigue of laser optics: laser-induced contamination

Arnold¹,

Rashvand²,

Willis³

et al. 2022

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Laser-induced contamination (LIC) can be a major concern of using UV laser systems. Surface contamination occurs via interactions between the UV laser and particulates, water vapor condensate, organics, and airborne molecular contaminates (AMC) from the environment or outgassing from system materials. A brief review of contamination of optics will lead into present results from long-term 355 nm quasi-CW laser transmission experiments at Edmund Optics. Time lapse microscopy was used to monitor nucleation and growth of surface contaminants. Laser burn boxes were constructed for use as a controlled UV LIC testbed; experimental results are presented on transmission losses for various material preparation methods.

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Lucas Willis

Laser mirror damage in germanium at 10.6 μm

Demonstration of Ignition Radiation Temperatures in Indirect-Drive Inertial Confinement Fusion Hohlraums

Laser damage in germanium

The topography of laser-irradiated germanium

UV fatigue of laser optics: laser-induced contamination

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