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Low Dose Imaging with Avalanche Amorphous Selenium Flat Panel Imager

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J Scheuermann

J Scheuermann1*, A Howansky1 , A Goldan1 , S Leveille2 , O Tousignant2 , K Tanioka1 , W Zhao1 , (1) Stony Brook University, Stony Brook, New York, (2) Analogic Canada, Saint-laurent, Quebec


MO-AB-BRA-7 (Monday, August 1, 2016) 7:30 AM - 9:30 AM Room: Ballroom A

Purpose: We present the first active matrix flat panel imager (AMFPI) capable of producing x-ray quantum noise limited images at low doses by overcoming the electronic noise through signal amplification by photoconductive avalanche gain (gav). The indirect detector fabricated uses an optical sensing layer of amorphous selenium (a-Se) known as High-Gain Avalanche Rushing Photoconductor (HARP). The detector design is called Scintillator HARP (SHARP)-AMFPI. This is the first image sensor to utilize solid-state HARP technology.

Methods: The detector’s electronic readout is a 24 x 30 cm² array of thin film transistors (TFT) with a pixel pitch of 85 μm. The HARP structure consists of a 15 μm layer of a-Se isolated from the high voltage (HV) and signal electrode by a 2 μm thick hole blocking layer and electron blocking layer, respectively, to reduce dark current. A 150 μm thick structured CsI scintillator with reflective backing and a fiber optic faceplate (FOP) was coupled to the semi-transparent HV bias electrode of the HARP structure. Images were acquired using a 30 kVp Mo/Mo spectrum typically used in mammography.

Results: Optical sensitivity measurements demonstrate that gav = 76 ± 5 can be achieved over the entire active area of the detector. At a constant dose to the detector of 6.67 μGy, image quality increases with gav until the effective electronic noise is negligible. Quantum noise limited images can be obtained with doses as low as 0.18 μGy.

Conclusion: We demonstrate the feasibility of utilizing avalanche gain to overcome electronic noise. The indirect detector fabricated is the first solid-state imaging sensor to use HARP, and the largest active area HARP sensor to date. Our future work is to improve charge transport within the HARP structure and utilize a transparent HV electrode.

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