Investigation of a direction sensitive sapphire detector stack at the 5 GeV electron beam at DESY-II

TL;DR

This study evaluates the radiation hardness and performance of a sapphire detector stack in a 5 GeV electron beam, demonstrating its potential as a cost-effective, radiation-tolerant alternative to diamond sensors in particle physics.

Contribution

The paper introduces a novel multichannel, direction-sensitive sapphire detector stack and provides experimental results on its charge collection efficiency and spatial response at high-energy electron beams.

Findings

Charge collection efficiency reaches about 10% at 950 V bias.

Signal size from electrons crossing the stack is approximately 22000 e.

Signal variation up to 20% across the detector surface was observed.

Abstract

Extremely radiation hard sensors are needed in particle physics experiments to instrument the region near the beam pipe. Examples are beam halo and beam loss monitors at the Large Hadron Collider, FLASH or XFEL. Currently artificial diamond sensors are widely used. In this paper single crystal sapphire sensors are considered as a promising alternative. Industrially grown sapphire wafers are available in large sizes, are of low cost and, like diamond sensors, can be operated without cooling. Here we present results of an irradiation study done with sapphire sensors in a high intensity low energy electron beam. Then, a multichannel direction-sensitive sapphire detector stack is described. It comprises 8 sapphire plates of 1 cm^2 size and 525 micro m thickness, metallized on both sides, and apposed to form a stack. Each second metal layer is supplied with a bias voltage, and the layers in between are connected to charge-sensitive preamplifiers. The performance of the detector was studied in a 5 GeV electron beam. The charge collection efficiency measured as a function of the bias voltage rises with the voltage, reaching about 10 % at 950 V. The signal size obtained from electrons crossing the stack at this voltage is about 22000 e, where e is the unit charge. The signal size is measured as a function of the hit position, showing variations of up to 20 % in the direction perpendicular to the beam and to the electric field. The measurement of the signal size as a function of the coordinate parallel to the electric field confirms the prediction that mainly electrons contribute to the signal. Also evidence for the presence of a polarisation field was observed.