Ionizing radiation effects on CMOS image sensors (CIS) manufactured using a 0.18 µm imaging technology are presented through the behavior analysis of elementary structures, such as field oxide FET, gated diodes, photodiodes and MOSFETs. Oxide characterizations appear necessary to understand ionizing dose effects on devices and then on image sensors. The main degradations observed are photodiode dark current increases (caused by a generation current enhancement), minimum size NMOSFET off-state current rises and minimum size PMOSFET radiation induced narrow channel effects. All these effects are attributed to the shallow trench isolation degradation which appears much more sensitive to ionizing radiation than inter layer dielectrics. Unusual post annealing effects are reported in these thick oxides. Finally, the consequences on sensor design are discussed thanks to an irradiated pixel array and a comparison with previous work is discussed

Bernard, Frédéric

Goiffon, Vincent

Magnan, Pierre

Rolland, Guy

Saint-Pé, Olivier

English

Ionizing radiation effects on CMOS image sensors implemented in 0.18 µm imaging technology are presented through the analysis of the behaviour of both elementary devices such as photodiodes, gated diodes, MOSFETs and also pixel array

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              To cite this version: Goiffon, Vincent and Magnan, Pierre and Saint-Pé, Olivier and Bernard, Frédéric and Rolland, Guy Total Dose Evaluation of Deep Submicron CMOS Imaging Technology Through Elementary Device and Pixel Array Behavior Analysis. (2008) In: Nuclear and Space Radiation Effects Conference (NSREC), 14 July 2008 - 18 July 2008 (Tucson, United States). (Unpublished)  Any correspondence concerning this service should be sent to the repository administrator: staff-oatao@inp-toulouse.fr  Open Archive Toulouse Archive Ouverte (OATAO)  OATAO is an open access repository that collects the work of Toulouse researchers and makes it freely available over the web where possible.  This is an author-deposited version published in: http://oatao.univ-toulouse.fr/  Eprints ID: 11390 Total Dose Evaluation of Deep Submicron CMOS Imaging Technology Through Elementary Device and Pixel Array Behavior Analysis*V. Goiffon1, P. Magnan1, O. Saint-Pé2, F. Bernard3, G. Rolland31 Toulouse Univ. , ISAE, Toulouse, France2 CNES, Toulouse, France3 EADS Astrium, Toulouse, FranceNuclear and Space and Radiation Effects ConferenceTucson, ArizonaJuly 18, 2008*PhD research supported by the French space agency (CNES) and EADS Astrium207/18/2008 - NSREC08 - V. Goiffon Motivations Why studying TID effects on CMOS image sensor again? Technologies have changed much since last CMOS image sensor ionizing dose effect studies Deep Submicron Technologies (DSM) (below 0.25 µm) Use of Shallow Trench Isolation (STI) instead of LOCOS Thinner gate oxides…Previous work conclusions can not be applied directly to CMOS image sensor manufactured using DSM CIS technology Process dedicated to CMOS Image Sensors (CIS) New dedicated “in-pixel” Pwell New optimized photodiode N implant…below 0,25 µm307/18/2008 - NSREC08 - V. Goiffon Talk outline Experimental details Technology characterization Oxide characterizations Device characterizations Effects on Image Sensor Conclusion and perspectives407/18/2008 - NSREC08 - V. Goiffon Experimental details CMOS technology used UMC CIS 0.18 µm Dedicated to imaging (CIS) 3.3 V devices (instead of 1.8 V) Measurements Low current (<10 fA) I-V test bench Controlled temperature : 23C γ-ray irradiations ONERA DESP 60Co facility Up to 1 kGy(Si) / 100 krad(Si) Dose rate : 3 Gy/h Several bias configurations Accelerated annealing Standard 1 week at 100C507/18/2008 - NSREC08 - V. Goiffon Talk outline Experimental details Technology characterization Oxide characterizations Device characterizations Effects on Image Sensor Conclusion and perspectives607/18/2008 - NSREC08 - V. Goiffon Oxide characterizationsILD-FETFOX-FET707/18/2008 - NSREC08 - V. Goiffon -20 0 20 40 6010-1410-1210-1010-810-610-410-2Gate to source voltage (V)Drain current (A)Before irrad.Shallow trench isolation (STI) : Field Oxide FETDrain current (A)Before irrad.1kGy grounded-Drain current (A)Before irrad.1kGy groundedGround. anneal.807/18/2008 - NSREC08 - V. Goiffon -20 0 20 40 6010-1410-1210-1010-810-610-410-2Gate to source voltage (V)Drain current (A)Before irrad.1kGy groundedGround. anneal.Shallow trench isolation (STI) : Field Oxide FET Trapped charge and interface states generation Limited trapped charge annealing Interface state annealing (as observed by Faccio et al. 2008)Trapped ChargeInterface state buildupandannealing907/18/2008 - NSREC08 - V. Goiffon -20 0 20 40 6010-1410-1210-1010-810-610-410-2Gate to source voltage (V)Drain current (A)Before irrad.1kGy groundedGround. anneal.1kGy biasedBias. anneal.Shallow trench isolation (STI) : Field Oxide FET Trapped charge and interface states generation Limited trapped charge annealing Interface state annealing (as observed by Faccio et al. 2008)Enhanced degradation under VGS = 3.3 V1007/18/2008 - NSREC08 - V. Goiffon Inter layer dielectric (ILD) : ILDFET0 10 20 30 40 50 6010-1610-1410-1210-1010-810-610-4Gate to source voltage (V)Drain current (A)Before irrad.Drain current (A)Before irrad.1 kGy unbiasedDrain current (A)Before irrad.1 kGy unbiasedGrounded anneal.1107/18/2008 - NSREC08 - V. Goiffon 0 10 20 30 40 50 6010-1610-1410-1210-1010-810-610-4Gate to source voltage (V)Drain current (A)B before irrad.B 1kGy unbiasedB 1kGy biasedB grounded anneal.B biased anneal.Inter layer dielectric (ILD) : ILDFET ILD less sensitive than STI No trapped charge annealing Significant interface state annealingEnhanced degradation under VGS = 3.3 V1207/18/2008 - NSREC08 - V. Goiffon Photodiode dark current increase (1)CIS standard photodiode0 0.2 0.4 0.6 0.8 110-1410-1310-1210-11Total ionizing dose (kGy)Dark current at 2.4V (A)Post anneal.CIS1307/18/2008 - NSREC08 - V. Goiffon 0 0.2 0.4 0.6 0.8 110-1410-1310-1210-11Total ionizing dose (kGy)Dark current at 2.4V (A)Post anneal.CISRFD-Pw ellPhotodiode dark current increase (1)CIS standard photodiodeRFD-Pwell1407/18/2008 - NSREC08 - V. Goiffon Photodiode dark current increase (2) This radiation induced dark current Is a generation current (Eact ~ 0.63 eV) Is proportional to the diode perimeter Increases when P doping decreases Anneals partially after one week at 100CInterface states This dark current increase is mainly due to a radiation induced interface statenumber increase in the depleted region extension in the P doped region.1507/18/2008 - NSREC08 - V. Goiffon -2 -1 0 1 2 310-1610-1410-1210-1010-810-610-4Gate to source voltage (V)Drain current (A)Before irradiationAfter 140 GyAfter 290 GyAfter 500 GyAfter 720 GyAfter 1000 GyAfter 168h at 100°CN-MOSFET leakage currentParasitic leakage paths No threshold voltage shift Off-state leakage current increase only Due to the parasitic lateral FET1607/18/2008 - NSREC08 - V. Goiffon 1 1.5 2 2.5 300.511.522.5x 10-5Source to gate voltage (V)Drain current (A)Before irradiationAfter 1 kGyAfter 168h at 100°CP-MOSFET  RINCERadiation Induced Narrow Chanel Effect (Faccio et al. 2005)Large Vt shift on minimum size PMOST0 0.2 0.4 0.6 0.8 1-1-0.50Ionizing dose (kGy)∆Vth (V)Post anneal.1707/18/2008 - NSREC08 - V. Goiffon Expected effects on image sensorsNo minimum size PMOST => No RINCENMOST leakage current negligible in voltage signal pathSensitive partThe pixel is the sensitive part1807/18/2008 - NSREC08 - V. Goiffon Expected effects on pixelJunction reverse generation current should dominate1907/18/2008 - NSREC08 - V. Goiffon Estimation vs measurementImage sensors dark current increase is only due to the photodiode generation current increase0 0.2 0.4 0.6 0.8 101020304050Total ionizing dose (kGy)Dark current increase (fA)Post anneal.Image sensor dark currentDiode generation currentImage sensorfeatures 3T pixel 128 x 128 pixels 10 µm pitch UMC CIS 0.18 µm2007/18/2008 - NSREC08 - V. Goiffon 0 200 400 600 800 100010-310-210-1100Total ionizing dose (Gy)Dark current (fA/µm)This study 0.18 µm CIS 3TMeasured effects on image sensors2107/18/2008 - NSREC08 - V. Goiffon Measured effects on image sensors0 200 400 600 800 100010-310-210-1100Total ionizing dose (Gy)Dark current (fA/µm)This study 0.18 µm CIS 3TRao et al. 0.18 µm CIS 4TPain et al. 0.25 µm 3TPain et al. 0.25 µm 3T hardenedEid et al. 0.35 µm 3T hardenedBogaerts et al. 0.50 µm 3T hardenedDSM CIS technologies are much more sensitive than what was observed in previous work2207/18/2008 - NSREC08 - V. Goiffon Talk outline Experimental details Technology characterization Oxide characterizations Device characterizations Effects on Image Sensor Conclusion and perspectives2307/18/2008 - NSREC08 - V. Goiffon Conclusion and perspectives Conclusion Ionizing radiation induced large dark current increases due to STI interface states located on the photodiode perimeter enhances by STI ∆Not & ∆Nit DSM CIS technology are more sensitive than older ones Thick oxides (STI and ILD) exhibited unusual annealing behaviors Future work and Perspectives Further study of irradiated thick oxides Photodiode dark current modeling from thick oxide ∆Not & ∆Nit Photodiode total dose hardening-by-design Radiation hard CMOS image sensor design using DSM CIS processThank you!Contact: vincent.goiffon@isae.fr

Total Dose Evaluation of Deep Submicron CMOS Imaging Technology Through Elementary Device and Pixel Array Behavior Analysis

Total dose evaluation of deep submicron CMOS imaging technology through elementary device and pixel array behavior analysis

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Total dose evaluation of deep submicron CMOS imaging technology through elementary device and pixel array behavior analysis

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