Mirror technology developed in this project will have many important applications in addition to light weight, low cost, large aperture space born telescopes. Because the mirrors will be constructed from ceramic, they will be thermally stable even at high temperatures, which will make them attractive for high power laser applications. Their low mass may make them attractive for use as solar power collectors (heliostats). To produce a custom, cavity back glass or ceramic mirror is currently cost prohibitive. The mirror technology developed in this proposal is far cheaper than current ceramic technologies, producing components lighter than glass. It also lends itself to mass production which will further reduce cost over custom made mirrors. "According to the U.S. Census Bureau, there were at least 500 companies engaged in the manufacturing of optical instruments and lenses in the late 1990s. The industry employed approximately 22,100 persons, and generated about $3.74 billion in shipments in 2000."
Earth science requires modest apertures of 2 to 4 meters in size, while deep space observation requires 12 to 30 meter class segmented primary mirrors for UV/optical or infrared wavelengths and 8 to 16 meter class segmented x-ray telescope mirrors which are cost effective. X-ray telescopes require 1 to 2 meter long grazing incidence segments. UV/optical telescopes require 1 to 3 meter class mirrors. IR telescopes require 2 to 3 meter class mirrors with cryo-deformations < 100 nm rms. Affordability or areal cost (cost per square meter of collecting aperture) rather than areal density, is probably the single most important system characteristic of these advanced optical systems. For example, both x-ray and normal incidence space mirrors currently cost $3M to $4M per square meter of optical surface area. This research effort seeks a cost reduction for precision optical components by 20X to 100X, to less than $100K per square meter.
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