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Abstract

Background

The lobster eye micro pore optics (MPO) plays a pivotal role in X-ray focusing, composed of thousands of hollow square microfibers. The channel error in MPO can profoundly impact its focusing performance. Due to the complex manufacturing process of MPO, there are numerous factors that can contribute to channel errors.

Objective

This paper investigates the impact of two key quality indicators of fiber, i.e., diameter precision and ovality, on the focusing performance of flat MPO.

Methods

During the actual production process of MPO, fibers with varying diameter precision and ovality are utilized, and point-to-point vacuum X-ray focusing equipment is used to assess MPO's focusing performance. Channel error models related to fiber diameter accuracy and ovality are established in the simulation.

Results

Experiments show that both the diameter precision and ovality of fiber influence MPO focusing abilities, with diameter precision primarily affecting the intensity and uniformity of the central point focus and the parallelism of the line foci, while ovality mainly affects the intensity and continuity of the line foci. Numerical simulation results reveal that tilt channel errors significantly affect the X-ray focusing effects.

Conclusions

These findings hold important guiding significance for the preparation process of square fibers and high quality X-ray focusing device.

Keywords

lobster eye micro pore optics square fiber diameter precision ovality X-ray optics

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Study on the influence of square fiber diameter quality on the optical characteristics of lobster eye X-ray micro pore optics

Abstract

Background

Objective

Methods

Results

Conclusions

Keywords

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References