We have investigated scintillator efficiency for MeV radiographic imaging. This paper discusses the modeled detection efficiency and measured brightness of a number of scintillator materials. An optical imaging camera records images of scintillator emission excited by a pulsed x-ray machine. The efficiency of various thicknesses of monolithic LYSO:Ce (cerium-doped lutetium yttrium orthosilicate) are being studied to understand brightness and resolution trade-offs compared with a range of micro-columnar CsI:Tl (thallium-doped cesium iodide) scintillator screens. The micro-columnar scintillator structure apparently provides an optical gain mechanism that results in brighter signals from thinner samples. The trade-offs for brightness versus resolution in monolithic scintillators is straightforward. For higher-energy x-rays, thicker materials generally produce brighter signal due to x-ray absorption and the optical emission properties of the material. However, as scintillator thickness is increased, detector blur begins to dominate imaging system resolution due to the volume image generated in the scintillator thickness and the depth of field of the imaging system. We employ a telecentric optical relay lens to image the scintillator onto a recording CCD camera. The telecentric lens helps provide sharp focus through thicker-volume emitting scintillators. Stray light from scintillator emission can also affect the image scene contrast. We have applied an optical light scatter model to the imaging system to minimize scatter sources and maximize scene contrasts.
[1]
Lin Yin,et al.
Simulation of the Cygnus Rod-Pinch Diode Using the Radiographic Chain Model
,
2009,
IEEE Transactions on Plasma Science.
[2]
Stephen E. Mitchell,et al.
Lithium fluoride TLD dose quality
,
2013,
2013 Abstracts IEEE International Conference on Plasma Science (ICOPS).
[3]
Wilfred Lewis,et al.
Performance of image intensifiers in radiographic systems
,
2000,
Electronic Imaging.
[4]
Mj Berger,et al.
Photon cross sections database. NIST Standard Reference Database 8 (XGAM)
,
1998
.
[5]
Kuppusamy Thayalan,et al.
Radiation Detection and Measurements
,
2014
.
[6]
Robert M. Malone,et al.
Alignment and testing of a telecentric zoom lens used for the Cygnus x-ray source
,
2013,
Optics & Photonics - Optical Engineering + Applications.
[7]
Robert D. Fiete,et al.
Modeling the Imaging Chain of Digital Cameras
,
2010
.
[8]
Michael R. Squillante,et al.
Structured CsI(Tl) scintillators for X-ray imaging applications
,
1997
.
[9]
Joshua R. Smith,et al.
Cygnus Dual Beam Radiography Source
,
2005,
2005 IEEE Pulsed Power Conference.