Study of radiation damage induced by 12 keV X-rays in MOS structures built on high resistivity n-type silicon

Abstract

Imaging experiments at the European X-ray Free Electron Laser (XFEL) require silicon pixel sensors with extraordinary performance specifications: Doses of up to 1 GGy of 12 keV photons, up to 105 12 keV photons per pixel of 200 μm × 200 μm arriving within less than 100 fs, and a time interval between XFEL pulses of 220 ns. To address these challenges, in particular the question of radiation damage, the properties of the SiO2 layer and of the Si-SiO2 interface using MOS capacitors manufactured on high resistivity n-type silicon irradiated to X-ray doses between 10 kGy and 1 GGy, have been studied. Measurements of Capacitance/Conductance-Voltage (C/G-V) at different frequencies, as well as Thermal Dielectric Relaxation Current (TDRC) have been performed. The data can be described by a radiation dependent oxide charge density and three dominant radiation-induced interface states with Gaussian-like energy distributions in the silicon band gap. It is found that the densities of the fixed oxide charges and of the three interface states increase up to dose values of approximately 10 MGy and then saturate or even decrease. The shapes and the frequency dependences of the C/G-V measurements can be quantitatively described by a simple model using the parameters extracted from the TDRC measurements.