Carbon Nanotube Devices: Properties, Modeling, Integration by Christofer Hierold, Oliver Brand, Gary K. Fedder, Visit

By Christofer Hierold, Oliver Brand, Gary K. Fedder, Visit Amazon's Jan G. Korvink Page, search results, Learn about Author Central, Jan G. Korvink, , Osamu Tabata

Following on from the 1st AMN quantity, this convenient reference and textbook examines the subject of nanosystem layout in additional element. It explains the actual and chemical fundamentals in the back of the layout and fabrication of nanodevices, protecting all vital, contemporary advances within the box, whereas introducing nanosystems to much less skilled readers.
the result's an enormous resource for a quick, actual assessment of the state-of-the-art of nanosystem cognizance, summarizing extra vital literature.Content:
Chapter 1 Carbon Nanotubes in Microelectronic functions (pages 1–41): Franz Kreupl
Chapter 2 Electromechanical Carbon Nanotube Transducers (pages 43–81): Christoph Stampfer and Christofer Hierold
Chapter three Carbon Nanotube Direct Integration into Microsystems (pages 83–124): Alain Jungen and Christofer Hierold
Chapter four Characterization of Carbon Nanotubes by means of Optical Spectroscopy (pages 125–180): Janina Maultzsch and Christian Thomsen
Chapter five Modeling the homes of Carbon Nanotubes for Sensor?Based units (pages 181–227): Cosmin Roman, Stephan Roche and Angel Rubio
Chapter 6 Multiscale Modeling and Simulation for Fluid Mechanics on the Nanoscale (pages 229–290): Petros Koumoutsakos
Chapter 7 Carbon Nanotube box Emission units (pages 291–309): John Robertson
Chapter eight Carbon Nanotube fuel Sensors (pages 311–349): John T. W. Yeow

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Extra resources for Carbon Nanotube Devices: Properties, Modeling, Integration and Applications

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Reifenberger, A simple, reliable technique for making electrical contact to multiwalled carbon nanotubes, Appl. Phys. Lett. 74 (1999) 323–325. 17 B. Bourlon, C. Miko, L. Forró, D. C. Glattli, A. Bachtold, Beyond the linearity of current–voltage characteristics in multiwalled carbon nanotubes, Semicond. Sci. Technol. 21 (2006) S33–S37. 18 A. Neumann, Chemical optimization of carbon nanotubes for electronic devices, Diploma Thesis, Technical University of Ilmenau, 2005. 19 M. Liebau, E. Unger, G.

B) Current density versus CNT density for the interdigital contacts at three different current levels. (c) On-resistance for varying CNT densities and three individual CNT resistances. device can deliver 8 kA cm−2 at an on-resistance of only 3 mΩ mm2. However, these optimistic values can only be obtained with challenging progress in the aligned fabrication of small-diameter semiconducting nanotubes. 5 Conclusions The promising properties of carbon nanotubes have sparked a huge world-wide activity to investigate these objects in many technical areas – not only in microelectronic applications.

R. Seidel, F. Kreupl, A. Graham, Integrated electronic component, US Patent Application 20060234080, 2006. M. Meyyappan, L. Delzeit, A. Cassell, D. Hash,Carbon nanotube growth by PECVD: 39 40 1 Carbon Nanotubes in Microelectronic Applications 35 36 37 38 39 40 41 42 43 a review, Plasma Sources Sci. Technol. 12 (2003) 205–216. F. Kreupl, A. P. Graham, G. S. Duesberg, W. Steinhögl, M. Liebau, E. Unger, W. Hönlein, Carbon nanotubes in interconnect applications, Microelectron. Eng. 64 (2002) 399–408.

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