Add to ORKGA demonstration x-ray optic has been produced by diamond turning and replication techniques that could revolutionize the fabrication of advanced mirror assemblies. The prototype optic was developed as part of the Advanced X-ray Astrophysics Facility - Spectrographic project (AXAF-S). The initial part of the project was aimed at developing and testing the replica technique so that it could potentially be used for the production of the entire mirror array comprised of up to 50 individual mirror shells
The optical surfaces for the Advanced X-ray Astrophysical Facility (AXAF), was studied. The applicab...
Angular resolution and photon-collecting area are the two most important factors that determine the ...
Ultra precision cutting with diamond tools enables flexible manufacturing of various surface shapes ...
Advanced optical systems for applications such as grazing incidence Wolter I x-ray mirror assemblies...
Ultra-precision diamond turning can deliver very accurate form, often less than 100nm P-V. A possibl...
The mirror assembly of the AXAF observatory consists of four concentric, confocal, Wolter type 1 tel...
Future x-ray astronomical missions, like the International X-ray Observatory (IXO), will likely requ...
NASAs Marshall Space Flight Center (MSFC) maintains an active research program toward the developmen...
This project is to demonstrate the capability to directly fabricate lightweight, high-resolution, gr...
Advanced optical systems for applications such as grazing incidence Wolter I x-ray mirror assemblies...
Optical freeforms are increasingly gaining interest for optical systems like telescopes and spectrom...
Current state-of the-art for x-ray optics fabrication calls for either the polishing of massive subs...
We describe the fabrication process for producing shallow-graze-angle mirrors for hard x-ray astrono...
Aspheric reflecting surfaces possessing extremely high surface finish and contour accuracy are often...
For optical systems consisting of metal (in general freeform) mirrors there exist several diamond tu...
The optical surfaces for the Advanced X-ray Astrophysical Facility (AXAF), was studied. The applicab...
Angular resolution and photon-collecting area are the two most important factors that determine the ...
Ultra precision cutting with diamond tools enables flexible manufacturing of various surface shapes ...
Advanced optical systems for applications such as grazing incidence Wolter I x-ray mirror assemblies...
Ultra-precision diamond turning can deliver very accurate form, often less than 100nm P-V. A possibl...
The mirror assembly of the AXAF observatory consists of four concentric, confocal, Wolter type 1 tel...
Future x-ray astronomical missions, like the International X-ray Observatory (IXO), will likely requ...
NASAs Marshall Space Flight Center (MSFC) maintains an active research program toward the developmen...
This project is to demonstrate the capability to directly fabricate lightweight, high-resolution, gr...
Advanced optical systems for applications such as grazing incidence Wolter I x-ray mirror assemblies...
Optical freeforms are increasingly gaining interest for optical systems like telescopes and spectrom...
Current state-of the-art for x-ray optics fabrication calls for either the polishing of massive subs...
We describe the fabrication process for producing shallow-graze-angle mirrors for hard x-ray astrono...
Aspheric reflecting surfaces possessing extremely high surface finish and contour accuracy are often...
For optical systems consisting of metal (in general freeform) mirrors there exist several diamond tu...
The optical surfaces for the Advanced X-ray Astrophysical Facility (AXAF), was studied. The applicab...
Angular resolution and photon-collecting area are the two most important factors that determine the ...
Ultra precision cutting with diamond tools enables flexible manufacturing of various surface shapes ...