AI Article Synopsis
- To achieve high precision in X-ray mirrors, a differential deposition method was utilized instead of traditional direct removal techniques.
- The method involved applying a thick film coating using a co-deposition approach, which helped maintain lower surface roughness by adding carbon to the platinum thin film.
- The fabrication process entailed precise control of the substrate movement and dwell time calculations to accurately shape the mirror, resulting in successful production of high-performance X-ray mirrors.
Article Abstract
To obtain the surface shape of an X-ray mirror with high precision, a differential deposition method was used instead of a direct removal method. To modify the mirror surface shape using the differential deposition method, it is necessary to coat it with a thick film, and the co-deposition method is used to suppress the increase in surface roughness. The addition of C to the Pt thin film, which is often used as an X-ray optical thin film, resulted in lower surface roughness compared with that with the Pt coating alone, and the stress change according to the thin film thickness was evaluated. Differential deposition controls the speed of the substrate during coating based on continuous motion. The stage was controlled by calculating the dwell time through deconvolution calculations based on the accurate measurement of the unit coating distribution and target shape. We successfully fabricated an X-ray mirror with high precision. This study indicated that an X-ray mirror surface could be manufactured by modifying the surface shape at a micrometer level through the coating. Changing the shape of existing mirrors can not only result in the manufacture of high-precision X-ray mirrors but also improve their performance.
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| http://dx.doi.org/10.1364/OE.480993 | DOI Listing |
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