Thales Research and Technology

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Presentation transcript:

Thales Research and Technology

Outline Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to fabricate CNTFETs Our approach for enhance selectivity Preliminary measurements Conclusions and Perspectives TNT10, Braga, 10/09/2010

Outline Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to fabricate CNTFETs Our approach for enhance selectivity Preliminary measurements Conclusions and Perspectives TNT10, Braga, 10/09/2010

Why CNT transistors for sensing applications? Advantages : Fabrication of very compact devices (around some µms) High sensitivity : Less than one ppm, it can reach 100ppt (NO2) it depends on the detection technique Versatility : They could be used for different gas families and biological molecules (also using functionalization to improve selectivity) Low Power consumption Very fast response and recovery time : The phenomenon physics concerns charges passage Reset performed by heating, photo-desadsorption using UV light or by inversion of the Gate potential (CNTFET) Room temperature utilization : they do not need high temperature to be effective Technological steps compatible with CMOS technology and batch fabrication: Relatively low cost technology (potential for batch fabrication) TNT10, Braga, 10/09/2010

Outline Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to fabricate CNTFETs Our approach for enhance selectivity Preliminary measurements Conclusions and Perspectives TNT10, Braga, 10/09/2010

Detection using CNTFET: working principle CNTFET = Carbon Nanotubes Field Effect Transistor Gas Drain CNT Source Silicon oxide Substrate (Gate) Carbon Nanotubes as the transistor channel (one single or a SWCNT mat) We analyze the change of the current between Source and Drain as a function of the Gate voltage (bottom gate configuration) TNT10, Braga, 10/09/2010

The Turn-on voltage changes as a function of the gas First gas detection using CNTFET: H.Dai (Stanford) Stanford, 2000 Drain CNT Source Silicon oxide Substrate ( Gate ) Gas Gas doping effect ? The Turn-on voltage changes as a function of the gas TNT10, Braga, 10/09/2010

Carbon Nanotubes transistors based sensors : Physics Gas Drain CNT Source Silicon oxide Substrate ( Gate ) R T TNT10, Braga, 10/09/2010

Carbon Nanotubes transistors based sensors : Physics Resin Drain CNT Source Silicon oxide Substrate ( Gate )  R T TNT10, Braga, 10/09/2010

Carbon Nanotubes transistors based sensors : Physics Resin Drain CNT Source Silicon oxide Substrate ( Gate )  R T Ph.Avouris (IBM, 1998) , H.Dai (Stanford, 2004 ), J.Zhang (Georgetown University 2006), Peng (2009) TNT10, Braga, 10/09/2010

The main interaction is at the Metal/CNT junction Carbon Nanotubes transistors based sensors : Physics The main interaction is at the Metal/CNT junction Source Drain CNT Silicon oxide Substrate (Gate) NOT A BULK PHENON It seems to be not correlated to a doping effect This seems to be true for short channel configuration <100µm TNT10, Braga, 10/09/2010

UCAM, MIT, Nanyang Technological University Peng et al., NanoLett. 9 (4) 2009 UCAM, MIT, Nanyang Technological University TNT10, Braga, 10/09/2010

Peng et al., NanoLett. 9 (4) 2009 TNT10, Braga, 10/09/2010

Peng et al., NanoLett. 9 (4) 2009 TNT10, Braga, 10/09/2010

Question :What actually happens at the contacts? Example : junction Au/CNT Au/CNT in Vacuum Au/CNT in Air N-Type junction P-Type junction Source Drain current change as a function of the oxygen concentration Ph.Avouris et al., Proceedings of the IEEE,Vol.91, n.11, 2003 TNT10, Braga, 10/09/2010

What happens at the Metal/CNT junction? Example : junction Au/CNT Au/CNT in Vacuum Au/CNT in Air N-Type junction P-Type junction Source Drain current change as a function of the oxygen concentration Ph.Avouris et al., Proceedings of the IEEE,Vol.91, n.11, 2003 TNT10, Braga, 10/09/2010

Quite high concentrations Electrode distance more than 300µm What happens in case of very large channels? If Channel length is more than 100µm the mat resistance can be compared to the contact resistance. In this case we can work in the so-called « resistive » configuration. 2mmx2mm Quite high concentrations and high recovery time Electrode distance more than 300µm TNT10, Braga, 10/09/2010

Outline Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to fabricate CNTFETs Our approach for enhance selectivity Preliminary measurements Conclusions and Perspectives TNT10, Braga, 10/09/2010

CNTFETs fabricated using SWCNTs mats : motivation Overall semiconductor effect (1/3 of the SWNTs are metallic) SWCNT by COMOCAT ~90% Advantages Strong fabrication time reduction (no need for AFM localization) Batch Fabrication (large surfaces reduction dramatically the cost) Better overall electrical control CNTFET S. Kumar et al., Phys. Rev. Lett. 95, 066802 (2005) S. Kumar et al., Applied Physiscs Letters, 88, 123505 (2006) Carbon Nanotubes Chains IDE electrodes TNT10, Braga, 10/09/2010

Outline Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to fabricate CNTFETs Our approach for enhance selectivity Preliminary measurements Conclusions and Perspectives TNT10, Braga, 10/09/2010

Improving selectivity Stanford DNA functionalization Polymer functionalization University of Pennsylvania Nanomix Desorption time Metal particles mat decoration Yonsei University (South Korea) TNT10, Braga, 10/09/2010

Different metal electrodes Our Approach : Working Principle (fingerprinting concept) Transfer characteristics Different metal electrodes IDS VGS IDS VGS IDS Drain Source VGS IDE configuration TNT10, Braga, 10/09/2010

Our Approach : Working Principle (fingerprinting concept) Gas molecules Transfer characteristics Different metal electrodes IDS VGS IDS VGS IDS Drain Source IDE configuration VGS The Selectivity is achieved using different metal electrodes : We analyze the relative change of transfer characteristics for each gas TNT10, Braga, 10/09/2010

Our Approach: gas fingerprinting using different metal/CNT junctions Aim : to obtain the electric fingerprinting of a specific gas Patent owned by Thales (2006) Principle: gas fingerprinting using CNTFETs with different metal electrodes TNT10, Braga, 10/09/2010

Outline Introduction : Nanocarb Lab. presentation Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to enhance selectivity Samples preparation Preliminary results using DMMP (simili-sarin gas) Conclusions and Perspectives TNT10, Braga, 10/09/2010

Stable Carbon Nanotube solution using specific solvent Sonication Nanotubes solution CNT solution before centrifugation SWCNT powder Centrifugation facility Surnatant after centrifugation Final solution TNT10, Braga, 10/09/2010

CNT deposition using Air-Brush Technique Not Uniform!!! Not effective!!! Not reproducible!!! Not suitable for industrial application!! heated substrate (~200°C) 100% of effective CNTFETs using Air-Brush Technique Drop-Casting was < 10%!!! TNT10, Braga, 10/09/2010

Deposition on 4 inches wafer but it could be used for larger surfaces!!! Spray-gun x z y Heating Platform TNT10, Braga, 10/09/2010

Reproducible Results with high Ion/Ioff ratio 1 chip (1cm²) 32 transitors 4 series with electrodes distance of 2µm, 5µm, 10µm, 15µm for each electrode distance, two electrode lengths -10 -5 5 10 1E-13 1E-12 1E-11 1E-10 1E-9 1E-8 1E-7 1140µm 15µm I DS I /I More than 5 orders!!! on off 15µm 550µm V G TNT10, Braga, 10/09/2010

Outline Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to fabricate CNTFETs Our approach for enhance selectivity Preliminary measurements Conclusions and Perspectives TNT10, Braga, 10/09/2010

Fingerprint of NO2 an NH3 : CNTFETs obtained by Air-brush deposition ΔI/I0 50 ppm of NO2 response ΔI/I0 After 10 minutes Strong increase t(min) ΔI/I0 Strong reduction 100 ppm of NH3 Perform with the Help of CEA LITEN J.P. Simonato and L. Caillier for ANR PNANO-07 project NANOSENSOFIN t(min) TNT10, Braga, 10/09/2010

Current change of 4 CNTFETs obtained using different metals after gas exposure (NO2 ,50ppm). TNT10, Braga, 10/09/2010

Outline Why CNT Transistors for sensing applications? Physics of Carbon Nanotubes sensors Our approach to fabricate CNTFETs Our approach for enhance selectivity Preliminary measurements Conclusions and Perspectives TNT10, Braga, 10/09/2010

Conclusions and perspectives Effective and reproducible CNTFETs based on SWCNTs mat obtained through low cost Air-brush deposition technique : suitable technique for industrial fabrication These CNTFETs are suitable for gas sensor applications Results using NO2 and NH3 demonstrate the fingerprinting concept : Each gas interacts specifically with each metal electrode NEXT STEPS To perform more systematic measurements using more gases using an optimized test bench and perform fusion and data analysis To reduce humidity effect using passivation of part of the SWCNTs mat (not the contacts) TNT10, Braga, 10/09/2010

Thank you for your attention! Recent publications Carbon Nanotubes based transistors composed of single-walled carbon nanotubes mats as gas sensors : a review, P.Bondavalli, Comptes Rendus de Physique, in press (2010) CNTFETs based gas sensors : patent review, P. Bondavalli, Recent Patents on Electrical Engineering, 3 (2010) CNTFET based gas sensors : State of the art and critical review, P.Bondavalli, P.Legagneux and D.Pribat, Sensors and Actuators B, Volume 140, Issue 1, 18 June 2009, Pages 304-318 TNT10, Braga, 10/09/2010