Timothé Allanche scite author profile

Timothé Allanche

3Publications

68Citation Statements Received

106Citation Statements Given

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Affiliations

Laboratoire Hubert Curien, Claude Bernard University Lyon 1, French National Centre for Scientific Research

Publications

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Radiation Hardening of Digital Color CMOS Camera-on-a-Chip Building Blocks for Multi-MGy Total Ionizing Dose Environments

Goiffon

Rolando

Corbière

et al. 2017

IEEE Trans. Nucl. Sci.

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International audienceThe Total Ionizing Dose (TID) hardness of digital color Camera-on-a-Chip (CoC) building blocks is explored in the Multi-MGy range using 60Co gamma-ray irradiations. The performances of the following CoC subcomponents are studied: radiation hardened (RH) pixel and photodiode designs, RH readout chain, Color Filter Arrays (CFA) and column RH Analog-to-Digital Converters (ADC). Several radiation hardness improvements are reported (on the readout chain and on dark current). CFAs and ADCs degradations appear to be very weak at the maximum TID of 6 MGy(SiO2), 600 Mrad. In the end, this study demonstrates the feasibility of a MGy rad-hard CMOS color digital camera-on-a-chip, illustrated by a color image captured after 6 MGy(SiO2) with no obvious degradation. An original dark current reduction mechanism in irradiated CMOS Image Sensors is also reported and discussed

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Total Ionizing Dose Effects on a Radiation-Hardened CMOS Image Sensor Demonstrator for ITER Remote Handling

Goiffon¹,

Rizzolo²,

Corbière³

et al. 2018

IEEE Trans. Nucl. Sci.

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Abstract-Total Ionizing Dose (TID) effects are studied on a radiation hardened by design (RHBD) 256x256-pixel CMOS image sensor (CIS) demonstrator developed for ITER remote handling by using X and γ-rays irradiations. The (color) imaging capabilities of the RHBD CIS are demonstrated up to 10 MGy(SiO2), 1 Grad(SiO2), validating the radiation hardness of most of the designed integrated circuit. No significant sensitivity (i.e. responsivity and color filter transmittance) or readout noise degradation is observed. The proposed readout chain architecture allows achieving a maximum output voltage swing larger than 1 V at 10 MGy(SiO2). The influence of several pixel layout (the gate oxide thickness, the gate overlap distance and the use of an in-pixel P+ ring) and manufacturing process parameters (photodiode doping profile, process variation) on the radiation induced dark current increase is studied. The nature of the dark current draining mechanism used to cancel most of the radiation induced degradation is also discussed and clarified.

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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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