Abstract
Scintillating crystals are used in numerous applications of ionizing radiation detectors. In time of flight positron emission tomography (TOF-PET) for example, both energy and coincidence time resolution (CTR) are important characteristics that could significantly benefit if more light from scintillators, otherwise trapped, could be collected by the photodetector. A novel and promising method to extract more efficiently the light produced in crystal scintillators with high index of refraction is to introduce a thin nanopatterned photonic layer on the readout surface. In this paper, we describe the patterning process of a photonic crystal layer made of TiO2 with 390 nm diameter ”pillars” in a square lattice with a periodicity of 580 nm and a structure thickness of 300 nm on one side of a 10x10x10 mm 3 LYSO cube. The production process used was nanoimprint lithography. A substantial increase in light yield of ≥ 50% has been measured in good agreement with our simulations. An interesting result from these measurements is that the improvement in light output is independent of whether the crystal is read out from its photonically patterned side or from the one opposite to it. For all cases studied, the energy resolution improved by a factor of 1.1. On the other hand, the CTR, being very threshold dependent, is unlike the light yield not subject to a constant improvement. It turns out that, at low thresholds, the gain (improvement) in CTR is limited to 1.2, and then rapidly increases to a value of more than 2 at higher thresholds. This is mainly explained by an additionally induced light transfer time spread of the photonic pattern. Several configurations with and without Teflon wrapping were investigated.
Highlights
Scintillating crystals are widely used for the detection of ionizing particles in various applications, e.g. in high energy physics calorimetry, medical detectors, and homeland security.An important characteristic of scintillators is their energy resolution
In time of flight positron emission tomography (TOF-PET) for example, both energy and coincidence time resolution (CTR) are important characteristics that could significantly benefit if more light from scintillators, otherwise trapped, could be collected by the photodetector
We describe the patterning process of a photonic crystal layer made of TiO2 with 390 nm diameter "pillars" in a square lattice with a periodicity of 580 nm and a structure thickness of 300 nm on one side of a 10x10x10 mm 3 LYSO cube
Summary
Scintillating crystals are widely used for the detection of ionizing particles in various applications, e.g. in high energy physics calorimetry, medical detectors, and homeland security. An important characteristic of scintillators is their energy resolution. In positron emission tomography (PET) applications, where scintillators are used to detect two 511 keV gammas from electron-positron annihilation, the energy resolution enables to filter out scattered and other background events having energies other than the 511 keV photoelectric events. High energy resolution (Eres) increases the signal to noise ratio and the detector sensitivity. The statistical contribution to the energy resolution Eres depends on the collected light in the following way: Eres ∝. 1 √LYcoll where LY coll denotes the measured light yield. The CTR depends on the measured light yield (LY): CTR ∝ 1 √LYcoll
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
