What question did this study set out to answer?

To investigate the use of laser-assisted cutting to manage the brittle-plastic transition in single-crystal calcium fluoride and reduce anisotropy.

April 1, 2026Open Access

Laser-Assisted Diamond Turning for Anisotropy Suppression in Calcium Fluoride

Key Points

To investigate the use of laser-assisted cutting to manage the brittle-plastic transition in single-crystal calcium fluoride and reduce anisotropy.
Conducted nano-scratch experiments to assess heating effects on cutting processes.
Utilized laser-assisted ultra-precision turning to create CaF2 optical microcavities.
Measured surface roughness and quality factor of fabricated microcavities.
Increased critical plastic cutting depth with heating, leading to reduced inter-plane differences.
Achieved surface roughness below 10 nm in fabricated microcavities.
Obtained a maximum quality factor of approximately 7.79 × 107.

Abstract

This paper proposes the use of laser-assisted cutting technology to control the brittle–plastic transition of single-crystal CaF2 through local thermal softening, thereby suppressing its processing anisotropy. Nano-scratch experiments show that heating significantly increases the critical plastic cutting depth of each crystal plane and reduces the inter-plane differences. Based on this, laser-assisted ultra-precision turning was used to fabricate CaF2 optical microcavities with a surface roughness below 10 nm, achieving a maximum quality factor of ~7.79 × 107, and significantly reducing the performance differences among different crystal orientations. The research indicates that this method can effectively promote uniform plastic flow on each crystal plane, providing an effective approach for the high-performance and consistent fabrication of anisotropic brittle optical components.

Laser-Assisted Diamond Turning for Anisotropy Suppression in Calcium Fluoride

Key Points

Abstract

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