Add to ORKGNew technology in grazing-incidence mirror fabrication and assembly is necessary to achieve sub-arcsecond optics for large-area x-ray telescopes. In order to define specifications, an understanding of performance sensitivity to design parameters is crucial. MSFC is undertaking a systematic study to specify a mounting approach, mirror substrate, and testing method. Because the lightweight mirrors are typically flimsy, they are susceptible to significant distortion due to mounting and gravitational forces. Material properties of the mirror substrate along with its thickness and dimensions significantly affect the distortions caused by mounting and gravity. A parametric study of these properties and their relationship to mounting and testing s...
Two adjustable X-ray optics approaches are being developed for thin grazing incidence optics for ast...
MSFC has a long history of developing full-shell grazing-incidence x-ray optics for both narrow (poi...
We are developing adjustable X-ray optics to use on a mission such as SMART-X (see posters 38.02, 38...
New technology in grazing-incidence mirror fabrication and assembly is necessary to achieve subarcse...
New technology in grazing-incidence mirror fabrication and assembly is necessary to achieve sub-arcs...
Future x-ray telescopes will likely require lightweight mirrors to attain the large collecting areas...
Future x-ray telescopes will likely require lightweight mirrors to attain the large collecting areas...
This project is to demonstrate the capability to directly fabricate lightweight, high-resolution, gr...
Grazing incidence mirrors for X-ray astronomy are usually designed in the parabola-hyperbola (Wolte...
We describe progress in the development of adjustable grazing incidence X-ray optics for 0.5 arcsec ...
In order to advance significantly scientific objectives, future x-ray astronomy missions will likely...
Lightweight and high resolution mirrors are needed for future space-based X-ray telescopes to achiev...
NASA's Marshall Space Flight Center (MSFC) engages in research, development, design, fabrication, co...
In order to advance significantly scientific objectives, future x-ray astronomy missions will likely...
Objective of this work is to define and initiate a long-term program to mature six inter-linked crit...
Two adjustable X-ray optics approaches are being developed for thin grazing incidence optics for ast...
MSFC has a long history of developing full-shell grazing-incidence x-ray optics for both narrow (poi...
We are developing adjustable X-ray optics to use on a mission such as SMART-X (see posters 38.02, 38...
New technology in grazing-incidence mirror fabrication and assembly is necessary to achieve subarcse...
New technology in grazing-incidence mirror fabrication and assembly is necessary to achieve sub-arcs...
Future x-ray telescopes will likely require lightweight mirrors to attain the large collecting areas...
Future x-ray telescopes will likely require lightweight mirrors to attain the large collecting areas...
This project is to demonstrate the capability to directly fabricate lightweight, high-resolution, gr...
Grazing incidence mirrors for X-ray astronomy are usually designed in the parabola-hyperbola (Wolte...
We describe progress in the development of adjustable grazing incidence X-ray optics for 0.5 arcsec ...
In order to advance significantly scientific objectives, future x-ray astronomy missions will likely...
Lightweight and high resolution mirrors are needed for future space-based X-ray telescopes to achiev...
NASA's Marshall Space Flight Center (MSFC) engages in research, development, design, fabrication, co...
In order to advance significantly scientific objectives, future x-ray astronomy missions will likely...
Objective of this work is to define and initiate a long-term program to mature six inter-linked crit...
Two adjustable X-ray optics approaches are being developed for thin grazing incidence optics for ast...
MSFC has a long history of developing full-shell grazing-incidence x-ray optics for both narrow (poi...
We are developing adjustable X-ray optics to use on a mission such as SMART-X (see posters 38.02, 38...