Inductance properties of silicon-in-grown horizontal carbon nanotubes

Proceedings - Electronic Components and Technology Conference

Volumn , Issue , 2010, Pages 1329-1334

  Sun, Minghui ^a   Xiao, Zhiyong ^a   Chai, Yang ^a   Li, Yuan ^a   Chan, Philip C H ^a  

^a HONG KONG UNIVERSITY OF SCIENCE AND TECHNOLOGY   (Hong Kong)

Author keywords

[No Author keywords available]

Indexed keywords

AS-GROWN; EXPERIMENTAL STUDIES; KINETIC INDUCTANCES; STATISTICAL DATA PROCESSING;

CARBON NANOTUBES; DATA PROCESSING;

INDUCTANCE;

EID: 77955206008     PISSN: 05695503     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1109/ECTC.2010.5490649     Document Type: Conference Paper

References (17)

1. Li, H. et al, "High-Frequency Effects in Carbon Nanotube Interconnects and Implications for On-Chip Inductor Design", IEDM Tech.Dig., 2008, pp. 525-528.
2. Mousa, O. F. et al, "A Novel Design of CNT-Based Embedded Inductors", Proc 59th Electronic Components and Technology Conf, San Diego, CA, May. 2009, pp. 497-501.
3. Nieuwoudt, A. et al, "Predicting the Performance of Low-Loss On-Chip Inductors Realized Using Carbon Nanotube Arrays", IEEE Transactions on Electron Devices, Vol.55, No.1 (2008), pp.298-312.
4. Tarkiainen, R. et al, "Multiwalled carbon nanotube: Luttinger versus Fermi liquid", Phys. Rev. B, Condens. Matter, Vol.64, No.19(2001), pp.195412.
5. Burke, J. P., "Luttinger Liquid Theory as a Model of the Gigahertz Electrical Properties of Carbon Nanotubes", IEEE Trans. Nanotechnol., Vol.1, No.3(2002), pp.129-144.
6. Naeemi, A. et al, "Compact Physical Models for Multiwall Carbon-nanotube Interconnects", IEEE Electron Device Lett., Vol.27, No.5 (2006), pp.338-340.
7. Zhang, M. et al, "Radio-frequency Transmission Properties of Carbon Nanotubes in a Field-Effect Transistor Configuration", IEEE Electron Device Lett., Vol.27, No.8(2006), pp.668-670.
8. Plombon, J. et al, "High-Frequency Electrical Properties of Individual and Arrayd Carbon Nanotubes", Applied Physics Lett., Vol.90, No.6(2007), pp.063-106.
9. Xiao, Z. et al, "Integration of Horizontal Carbon Nanotube Devices on Silicon Substrate Using Liquid Evaporation", to be presented in 60th Electronic Components and Technology Conf., Las Vegas, NV, June. 2010.
10. Advanced Design System, Agilent Technologies, http://www.home.agilent. com/agilent/product.jspx?nid=-34346.0.00&cc=US&lc=eng
11. Li, H. et al, "High-Frequency Analysis of Carbon Nanotube Interconnects and Implications for On-Chip Inductor Design", IEEE Transactions on Electron Devices, Vol.56, No.10 (2009), pp.2202-2214.
12. Yamada, T. et al, "Size-selective Growth of Doublewalled Carbon Nanotube Forests from Engineered Iron Catalysts", Nature Nanotechnology, Vol.1, No.2(2006), pp.131-136.
13. Agilent Technologies Inc., "Network Analysis Basics -Applying Error Correction To Network Analyzer Measurements (AN 1287-3)", 2002.
14. Pozar, D.M., Microwave Engineering, Wiley (New York, 2005), pp. 174-183.
15. Rice, P. et al, "Broadband Electrical Characterization of Multiwalled Carbon Nanotubes and Contacts", Nano Letters, Vol.7, No.4(2007), pp.1086-1090.
16. Huo, X. et al, "Silicon-Based High-Q Inductors Incorporating Electroplated Copper and Low-K BCB Dielectric", IEEE Electron Device Lett., Vol.23, No.9 (2002), pp.520-522. (Pubitemid 35022942)
17. Tselev, A. et al, "Microwave Impedance Spectroscopy of Dense Carbon Nanotube Arrays", Nano Letters, Vol.8, No.1(2008), pp.152-156.