Study of X-ray Radiation Damage in Silicon Sensors

TL;DR

This study investigates how high-dose X-ray irradiation affects silicon sensors used in XFEL applications, focusing on microscopic defects and electrical property changes to optimize sensor design for extreme radiation environments.

Contribution

It provides detailed measurements of defect densities and electrical changes in silicon sensors as a function of X-ray dose, and uses simulations to optimize sensor design for high-radiation conditions.

Findings

Oxide charge density saturates at high doses.

Defects increase depletion voltage and leakage current.

Electron accumulation layer forms at the Si-SiO2 interface.

Abstract

The European X-ray Free Electron Laser (XFEL) will deliver 30,000 fully coherent, high brilliance X-ray pulses per second each with a duration below 100 fs. This will allow the recording of diffraction patterns of single complex molecules and the study of ultra-fast processes. Silicon pixel sensors will be used to record the diffraction images. In 3 years of operation the sensors will be exposed to doses of up to 1 GGy of 12 keV X-rays. At this X-ray energy no bulk damage in silicon is expected. However fixed oxide charges in the insulating layer covering the silicon and interface traps at the Si-SiO2 interface will be introduced by the irradiation and build up over time. We have investigated the microscopic defects in test structures and the macroscopic electrical properties of segmented detectors as a function of the X-ray dose. From the test structures we determine the oxide charge density and the densities of interface traps as a function of dose. We find that both saturate (and even decrease) for doses between 10 and 100 MGy. For segmented sensors the defects introduced by the X-rays increase the full depletion voltage, the surface leakage current and the inter-pixel capacitance. We observe that an electron accumulation layer forms at the Si-SiO2 interface. Its width increases with dose and decreases with applied bias voltage. Using TCAD simulations with the dose dependent parameters obtained from the test structures, we are able to reproduce the observed results. This allows us to optimize the sensor design for the XFEL requirements.