Abstract
Tracking detectors at future high luminosity hadron colliders are expected to be able to stand unprecedented levels of radiation as well as to efficiently reconstruct a huge number of tracks and primary vertices. To face the challenges posed by the radiation damage, new extremely radiation hard materials and sensor designs will be needed, while the track and vertex reconstruction problem can be significantly mitigated by the introduction of detectors with excellent timing capabilities. Indeed, the time coordinate provides extremely powerful information to disentangle overlapping tracks and hits in the harsh hadronic collision environment. Diamond 3D pixel sensors optimised for timing applications provide an appealing solution to the above problems as the 3D geometry enhances the already outstanding radiation hardness and allows to exploit the excellent timing properties of diamond. We report here the first full timing characterisation of 3D diamond sensors fabricated by electrode laser graphitisation in Florence. Results from a 270MeV pion beam test of a first prototype and from tests with a β source on a recently fabricated 55×55μm2 pitch sensor are discussed. First results on sensor simulation are also presented.
Highlights
One of the major problems to overcome in the design of tracking detectors at future high luminosity hadron colliders is represented by the unprecedented flux of ionising radiation through the sensors
We report on the first full timing characterisation of 3D diamond sensors fabricated by electrode laser graphitisation at the INO-CNR laboratory in Florence
Minimum ionising electrons with energies between ∼1 MeV and ∼2.3 MeV were selected by detecting the Cherenkov light emitted in the 8 mm diameter, 5 mm thick quartz entrance window of a Photonis PP2365Z micro-channel plate photomultuplier (MCP) placed downstream the diamond sensor, which provided a very precise time reference
Summary
One of the major problems to overcome in the design of tracking detectors at future high luminosity hadron colliders is represented by the unprecedented flux of ionising radiation through the sensors. The invention of 3D solid state detectors [2], with column-like charge-collecting electrodes built in the sensor bulk, provided a very promising solution to these challenges. The charge collection time is dramatically reduced down to about 100 ps allowing the realisation of tracking devices with time resolution at the level of 10 ps [3]. Micro-fabrication of electrodes by laser graphitisation of the crystal bulk [5] enabled the construction of 3D diamond detectors [6,7,8] that showed excellent detection properties [9] as well as very promising results on radiation hardness [10]. The 3D geometry, as pointed out before, allows to reach excellent time resolutions making 3D diamond detectors ideal candidates for tracking systems at future accelerators.
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