Time of Flight: the scintillator perspective

1. Time of Flight: the scintillator perspective Paul Lecoq CERN, Geneva

2. Whereis the limit? • Philips and Siemens TOF PET achieve • 550 to 650ps timing resolution • About 9cm localizationalong the LOR • Can weapproach the limit of 100ps (1.5cm)? • Can scintillatorssatisfythis goal?

3. Timing parameters • General assumption , based on Hymantheory • For the scintillator the important parameters are • Time structure of the pulse • Light yield • Light transport • affecting pulse shape, photon statistics and LY decay time of the fast component Photodetector excess noise factor number of photoelectronsgenerated by the fast component

4. Light output: LYSO example • Statistics on about 1000 LYSO pixels 2x2x20mm3 • produced by CPI • for the ClearPEM-Sonicproject (CERIMED) • Mean value = 18615 ph/MeV • For 511 KeV and 25%QE: 2378 phe • Assuming ENF= 1.1 • Nphe/ENF ≈ 2200 phe

5. Statistical limit on timing resolution • W(Q,t) is the time interval distribution between photoelectrons • = the probability density that the interval between event Q-1 and event Q is t • = time resolution when the signal is triggered on the Qth photoelectron t = 40 ns t = 40 ns Nphe=2200 LSO Nphe Nphe Nphe Nphe

6. Light generation 5d Rare Earth 4f

7. Rise time • Rise time is as important as decay time

8. Photon countingapproach LYSO, 2200pe detected, td=40ns tr=0.5ns tr=1ns tr=0ns tr=0.2ns

9. Fasterthan Ce3+?Intrinsiclimitat 17ns • Cross-Luminescentcrystals (veryfast, low LY) • BaF2 (1400ph/MeV) but 600ps decay time produces more photons in the first ns (1100) than LSO (670)! • Direct bandgapsemiconductorsS. Derenzo, SCINT2001 • Sub-nsband-to-bandrecombination in ZnO, CuI,PbI2, HgI2 • Nanocrystals • Bright and sub-nsemission due to quantum confinement • Pr3+ • Pr3+ 5d-4f transition isalways 1.55eV higherthan for Ce3+

10. UltimatelyfastusingCerenkovemission? • Evenlowenegyg ray produceCerenkovemission in dense, high n materials • This emissionisinstantaneouswith a 1/l2spectrum * Lowwavelengthcut-off set at 250nm for calculations on LSO, LuAG and LuAP Ce absorption bands subtractedfromCerenkovtransparencywindow

11. LuAGCerenkov/LYSO Scintillation coincidencemeasurement LuAG 2013 (undoped -> shows no scintillation) LSO 1121 22Na FWHM=374ps LuAG=259ps Crystals wrapped on 5 sides with teflon. PMT left (2150V) 8cm 8cm PMT right (1500V) Scope CFD FWHM=650ps LuAG=587ps Coincidence: Th_left=-4mV, th_right=-500mV

12. Light Transport • -49° < θ < 49° Fastforwarddetection 17.2% • 131° < θ < 229° Delayed back detection 17.2% • 57° < θ < 123° Fast escape on the sides 54.5% • 49° < θ < 57° and 123° < θ < 131° infinitebouncing11.1% For a 2x2x20 mm3 LSO crystal Maximum time spreadrelated to difference in travelpathis 424 pspeak to peak ≈162 ps FWHM

13. Photoniccrystals to improve light extraction Periodic medium allowing to couple light propagation modes inside and outside the crystal 24% 34% M. Kronberger, E. Auffray, P. Lecoq, Probing the concept of Photonics Crystals on Scintillating Materials TNS on Nucl. Sc. Vol.55, Nb3, June 2008, p. 1102-1106

14. Expected Light Output Gain for differentcrystals BGO LuAG:Ce Light gain 1.92 Light gain 2.11 LYSO LuAP Light gain 2.08 Light gain 2.1 Litrani + CAMFR simulation

15. How does the PhCwork? Diffracted modes interfere constructively in the PhC- grating and are therefore able to escape the Crystal Crystal- air interface with PhC grating: Section of the plane crystal- air interface: (EM – fieldplot) θ>θc Total Reflection at the interface θ>θc Extracted Mode

16. PhC fabrication Nano Lithography • PhC is produced in cooperation with the INL (Institut des Nanotechnologies de Lyon) • Three step approach: • Sputter deposition of an auxiliary layer • Electron beam lithography (EBL) • Reactive ion etching (RIE) RAITH® lithography kit:

17. PhC fabrication Ion Bombardment z z a Reactive Ion Etching (RIE) • Chemically reactive plasma removes Si3N4 not covered by the resist • Change the composition of the reactive plasma to remove the resist (PMMA) without etching the Si3N4 PMMA Resist Si3N4 Si3N4 Hole depth: 300nm ITO ITO Scintillator Scintillator y y hole diameter: 200nm x x

18. PhC fabrication Results • Scanning Electron Images: D = 200nm a = 340nm

19. PhC first results • Use larger LYSO crystal: 10x10mm2 to avoidedgeeffects • 6 different patches (2.6mm x 1.2mm) and 1 (1.2mm x 0.3mm) of differentPhC patterns 0° 45° Preliminary

20. PhCimproveslight extraction eficiency But also collimation of the extracted light

21. Conclusions • Timing resolutionimproveswithlowerthreshold • Ultimateresolutionimplies single photon counting • High light yieldismandatory • 100’000ph/MeV achievablewithscintillators • Shortdecay time • 15-20ns is the limit for brightscintillators (LaBr3) • 1ns achievable but withpoor LY • Crossluminescentmaterials • Severelyquenchedself-activatedscintillators • SHORT RISE TIME • Difficult to break the barrier of 100ps

22. Conclusions New approaches? • Crystalswith a highlypopulateddonor band (ZnO) • Metamaterialsloadedwith quantum dots • Make use of Cerenkov light • Improve light collection withphotoniccrystals

23. Our Team • CERN • Etiennette Auffray • Stefan Gundacker • HartmutHillemanns • Pierre Jarron • Arno Knapitsch • Paul Lecoq • Tom Meyer • Kristof Pauwels • François Powolny • Nanotechnology Institute, Lyon • Jean-Louis Leclercq • Xavier Letartre • ChristianSeassal