TY - THES AB - Physics with X-rays spans from observing large scales in X-ray astronomy down to small scales in material structure analyses with synchrotron radiation. Both fields of research require imaging detectors featuring spectroscopic resolution for X-rays in an energy range of 0.1keV to 20.0keV. Originally driven by the need for an imaging spectrometer on ESA's X-ray astronomy satellite mission XMM-Newton, X-ray pnCCDs were developed at the semiconductor laboratory of the Max-Planck-Institute. The pnCCD is a pixel array detector made of silicon. It is sensitive over a wide band from near infrared- over optical- and UV-radiation up to X-rays. This thesis describes the dynamics of signal electrons from the moment after their generation until their collection in the potential minima of the pixel structure. Experimentally, a pinhole array was used to scan the pnCCD surface with high spatial resolution. Numerical simulations were used as a tool for the modeling of the electrical conditions inside the pnCCD. The results predicted by the simulations were compared with the measurements. Both, experiment and simulation, helped to establish a model for the signal charge dynamics in the energy range from 0.7keV to 5.5keV. More generally, the presented work has enhanced the understanding of the detector system on the basis of a physical model. The developed experimental and theoretical methods can be applied to any type of array detector which is based on the full depletion of a semiconductor substrate material. AU - Kimmel, Nils DA - 2008 KW - Röntgenastronomie KW - Bauelementephysik KW - Beweglichkeit KW - Röntgenstrahlung KW - Charge-Coupled-Device KW - Radiation Detector KW - X-ray Astronomy KW - Synchrotron Radiation KW - Electron Mobility LA - eng PY - 2008 TI - Analysis of the charge collection process in solid state X-ray detectors UR - https://nbn-resolving.org/urn:nbn:de:hbz:467-3885 Y2 - 2024-11-22T08:56:15 ER -