Cyprien Muller scite author profile

Cyprien Muller

3Publications

20Citation Statements Received

32Citation Statements Given

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Affiliations

Laboratoire Hubert Curien, CEA DAM Île-de-France, Claude Bernard University Lyon 1

Publications

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Radiation Hardness Comparison of CMOS Image Sensor Technologies at High Total Ionizing Dose Levels

Rizzolo

Goiffon

Corbière

et al. 2019

IEEE Trans. Nucl. Sci.

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The impact of the manufacturing process on the radiation-induced degradation effects observed in CMOS image sensors (CISs) at the MGy total ionizing dose (TID) levels is investigated. Moreover, the vulnerability of the partially pinned PHDs at moderate-to-high TIDs is evaluated for the first time to our knowledge (PHD stands for "photodiode"). It is shown that the 3T-standard partially pinned PHD has the lowest dark current before irradiation, but its dark current increases to ∼1 pA at 10 kGy(SiO 2). Beyond 10 kGy(SiO 2), the pixel functionality is lost. The comparison between several CIS technologies points out that the manufacturing process impacts the two main radiation-induced degradations: the threshold voltage shift of the readout chain MOSFETs and the dark current increase. For all the tested technologies, 1.8-V MOSFETs exhibit the lower threshold voltage shift, and the nMOSFETs are the most radiation tolerant. Among all the tested devices, 1.8-V sensors achieve the best dark current performance. Several radiationhardening-by-design solutions are evaluated at the MGy level to improve further the understanding of CIS radiation hardening at extreme TID.

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Growth and Decay Kinetics of Radiation-Induced Attenuation in Bulk Optical Materials

Girard¹,

Allanche²,

Paillet³

et al. 2018

IEEE Trans. Nucl. Sci.

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Photobleaching Effect on Infrared Radiation-Induced Attenuation of Germanosilicate Optical Fibers at MGy Dose Levels

Campanella

Guttilla

Morana

et al. 2021

IEEE Trans. Nucl. Sci.

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Cyprien Muller

Radiation Hardness Comparison of CMOS Image Sensor Technologies at High Total Ionizing Dose Levels

Growth and Decay Kinetics of Radiation-Induced Attenuation in Bulk Optical Materials

Photobleaching Effect on Infrared Radiation-Induced Attenuation of Germanosilicate Optical Fibers at MGy Dose Levels

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