1. High-resolution, lightweight, and low-cost x-ray optics for the Lynx observatory
- Author
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Michal Hlinka, Michael P. Biskach, Peter M. Solly, John D. Kearney, Ryan S. McClelland, Raul E. Riveros, William W. Zhang, Ai Numata, Kim D. Allgood, James R. Mazzarella, Timo T. Saha, and Kai-Wing Chan
- Subjects
Fabrication ,business.industry ,Computer science ,Mechanical Engineering ,Process (computing) ,Polishing ,Astronomy and Astrophysics ,Substrate (printing) ,Modular design ,01 natural sciences ,Automation ,Electronic, Optical and Magnetic Materials ,010309 optics ,Space and Planetary Science ,Control and Systems Engineering ,0103 physical sciences ,Production schedule ,business ,010303 astronomy & astrophysics ,Instrumentation ,Throughput (business) ,Computer hardware - Abstract
We describe an approach to build an x-ray mirror assembly that can meet Lynx’s requirements of high-angular resolution, large effective area, light weight, short production schedule, and low-production cost. Adopting a modular hierarchy, the assembly is composed of 37,492 mirror segments, each of which measures ∼100 mm × 100 mm × 0.5 mm. These segments are integrated into 611 modules, which are individually tested and qualified to meet both science performance and spaceflight environment requirements before they in turn are integrated into 12 metashells. The 12 metashells are then integrated to form the mirror assembly. This approach combines the latest precision polishing technology and the monocrystalline silicon material to fabricate the thin and lightweight mirror segments. Because of the use of commercially available equipment and material and because of its highly modular and hierarchical building-up process, this approach is highly amenable to automation and mass production to maximize production throughput and to minimize production schedule and cost. As of fall 2018, the basic elements of this approach, including substrate fabrication, coating, alignment, and bonding, have been validated by the successful building and testing of single-pair mirror modules. In the next few years, the many steps of the approach will be refined and perfected by repeatedly building and testing mirror modules containing progressively more mirror segments to fully meet science performance, spaceflight environments, as well as programmatic requirements of the Lynx mission and other proposed missions, such as AXIS.
- Published
- 2019