Title:
AXAF HXDS germanium solid state detectors
Authors:
McDermott, Walter C.; Kellogg, Edwin M.; Wargelin, Bradford J.; Evans, Ian N.; Vitek, S. A.; Tsiang, Eugene Y.; Schwartz, Daniel A.; Edgar, Richard J.; Kraft, Stefan; Scholze, Frank; Thornagel, R.; Ulm, Gerhard; Weisskopf, Martin C.; O'dell, Stephen L.; Tennant, A. F.; Kolodziejczak, Jeffery J.; Zirnstein, G.
Affiliation:
AA(Smithsonian Astrophysical Observatory) AI(Physikalisch-Technische Bundesanstalt) AM(NASA
Marshall Space Flight Ctr.) AP(Universities' Space Research Association)
Publication:
Proc. SPIE Vol. 3113, p. 535-543, Grazing Incidence and Multilayer X-Ray Optical
Systems, Richard B. Hoover; Arthur B. Walker; Eds.
Publication Date:
07/1997
Abstract:
The design, calibration, and performance of the high purity germanium (HPGe) solid state detectors
(SSDs) used in the calibration of the Advanced X-ray Astrophysics Facility high resolution mirror
assembly (HRMA) is discussed. The focal plane SSD was used with various apertures to measure the
point response function, as well as the effective area of the mirror. The good energy resolution of the
detector allowed the effective energy of the mirrors to be measured with a single exposure using a
continuum source. The energy resolution was also exploited in measuring the molecular contamination
on the mirror surfaces. The SSDs are the transfer detector standards for the HRMA calibration over the
energy range from 700 eV to 10 keV. The calibration of the SSDs was performed mostly at the PTB
radiometry laboratory using the electron storage ring BESSY. The spectral and spacial distribution of
the undispersed synchrotron radiation can be calculated from first principles using the Schwinger
Equation. With the electron storage ring being run in a reduced current mode of a few electrons,
uncertainties in the calculated flux are below 1%. A comparison of the measured and calculated flux
made it possible to determine the detector efficiency with an uncertainty of typically 1%. Electronic
effects such as pile- up, count rate linearity and deadtime have been investigated.