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TECHNIQUES OF SYNTHESIZING CARBON NANOTUBE FETS FOR INTEGRATED CIRCUITS GAO, Feng S.I.D 20219798.

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Presentation on theme: "TECHNIQUES OF SYNTHESIZING CARBON NANOTUBE FETS FOR INTEGRATED CIRCUITS GAO, Feng S.I.D 20219798."— Presentation transcript:

1 TECHNIQUES OF SYNTHESIZING CARBON NANOTUBE FETS FOR INTEGRATED CIRCUITS GAO, Feng S.I.D 20219798

2 PART I. NANOTUBE PLACEMENT PART II. COMPLEMENTARY DEVICES PART III. IMPERFECTION REMEDY

3 2. Deposit NMPI (Self Aligned) 4. Ion exchange reaction 3. Aqueous CNT solutions preparation Self-Assembly Approach [1,2] NANOTUBE PLACEMENT [1] Park, Hongsik, et al. "High-density integration of carbon nanotubes via chemical self-assembly." Nature nanotechnology 7.12 (2012): 787-791. [2] Wu, Justin, et al. "Top ‐ Down Patterning and Self ‐ Assembly for Regular Arrays of Semiconducting Single ‐ Walled Carbon Nanotubes." Advanced Materials 26.35 (2014): 6151-6156.

4 Dielectrophoresis [3] NANOTUBE PLACEMENT [3] Shekhar, Shashank, Paul Stokes, and Saiful I. Khondaker. "Ultrahigh density alignment of carbon nanotube arrays by dielectrophoresis." ACS nano 5.3 (2011): 1739-1746. CNT density controlled by solution concentration ranges from 0.5 – 30 SWNT/ μ m 1. Pre-pattern electrodes 2. Oxygen plasma cleaning 3.DEP with DC 5 Vpp at 300kHz for 30s 4. Blown dry by N 2 gas

5 NANOTUBE PLACEMENT Transfer Approach (Langmuir–Schaefer Method) [4] Semiconductor CNT purity: 99% CNT density: 500 tubes/μm (full converage) [4] Cao, Qing, et al. "Arrays of single-walled carbon nanotubes with full surface coverage for high - performance electronics." Nature nanotechnology 8. 3 (2013): 180 - 186.

6 Controlled Growth [5] NANOTUBE PLACEMENT [5] Papadopoulos, Chris, and Badr Omrane. "Nanometer ‐ scale Catalyst Patterning for Controlled Growth of Individual Single ‐ walled Carbon Nanotubes." Advanced Materials 20.7 (2008): 1344-1347. 1.Pattern catalyst 2. Grow CNT 3. Fabricate electrodes and gates

7 COMPLEMENTARY DEVICES 1. Contact Controlled Devices Type [6] High Work Function Metal (Pd, Au) Femi Level Near to Valence Band p-FET Low Work Function Metal (Sc, Y, Er) Femi Level Near to Conduction Band n-FET Problem: Low work function metals are readily oxidized Solution: Cover with inert metal and passivation layer [6] Han, S-J., et al. "Carbon nanotube complementary logic based on erbium contacts and self-assembled high purity solution tubes." IEEE Int. Electron Dev. Meet 19 (2013): 1-19.

8 COMPLEMENTARY DEVICES 2. Dielectric Controlled Device Type [7] 3. Chemical Doping for n-FET [8] n-FETp-FET [7] Franklin, Aaron D., et al. "Carbon nanotube complementary wrap-gate transistors." Nano letters 13.6 (2013): 2490-2495. [8] Javey, Ali, et al. "High performance n-type carbon nanotube field-effect transistors with chemically doped contacts." Nano letters 5.2 (2005): 345-348. Potassium (K) Doping, Introduce electron carriers

9 REMEDY FOR IMPERFECTION 1. Cleaning metallic CNTs [9] G D S G D S Apply high voltage Breakdown voltage of semiconductor CNT is larger than metallic CNT [9] Kim, Sunkook, et al. "Current on/off ratio enhancement through the electrical burning process in ambient with/without oxygen for the generation of high-performance aligned single- walled carbon nanotube field effect transistors." Applied Physics Letters 97.17 (2010): 173102. m-CNTs-CNT

10 REMEDY FOR IMPERFECTION 2. Mis-positioned CNT Immune Design [10] [10] Zhang, Jie, et al. "Robust digital VLSI using carbon nanotubes." IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems 31.4 (2012): 453-471. Etched Regions Mis-positioned caused error After etch Mispositioned CNT-immune Layout for SOP form

11 Thanks

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