Nanotechnology-Enabled Sensors

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280 Chapter 5: Characterization Techniques for Nanomaterials 76 M. J. Pelletier, Analytical applications of Raman spectroscopy (Blackwell Science, Malden, USA, 1999). 77 T. Vo-Dinh, Trac-Trends in Analytical Chemistry 17, 557-582 (1998). 78 R. E. Littleford, D. Graham, W. E. Smith, and I. Khan, in Encyclopedia of Analytical Science, edited by C. F. Poole, A. Townshend, and P. J. Worsfold (Academic Press, New York, USA, 2004). 79 M. Fleischmann, P. J. Hendra, and McQuilla.Aj, Chemical Physics Letters 26, 163-166 (1974). 80 D. L. Jeanmaire and R. P. van Duyne, Journal of Electroanalytical Chemistry 84, 1-20 (1977). 81 M. Moskovits, in Surface-Enhanced Raman Scattering: Physics and Applications; Vol. 103 (Springer-Verlag, Berlin, 2006), p. 1-17. 82 A. Tao, F. Kim, C. Hess, J. Goldberger, R. R. He, Y. G. Sun, Y. N. Xia, and P. D. Yang, Nano Letters 3, 1229-1233 (2003). 83 D. L. Stokes and T. Vo-Dinh, <strong>Sensors</strong> and Actuators B-Chemical 69, 28-36 (2000). 84 M. von Ardenne, in Advances in electronics and electron physics. Supplement 16: The beginnings of electron microscopy, edited by P. W. Hawkes (Academic Press, Orlando, USA, 1984). 85 H.-J. Butt, K. Graf, and M. Kappl, Physics and chemistry of interfaces (Wiley-VCH, Weinheim, Germany, 2003). 86 S. Amelinckx, D. van Dyck, J. van Landuyt, and G. van Tandeloo, Electron microscopy: principles and fundamentals (Wiley-VCH, Weinheim, Germany, 2003). 87 A. C. C. Yu, M. Mizuno, Y. Sasaki, M. Inoue, H. Kondo, I. Ohta, D. Djayaprawira, and M. Takahashi, Applied Physics Letters 82, 4352-4354 (2003). 88 L. Valentini, I. Armentano, J. M. Kenny, C. Cantalini, L. Lozzi, and S. Santucci, Applied Physics Letters 82, 961-963 (2003). 89 F. Caruso, D. N. Furlong, K. Ariga, I. Ichinose, and T. Kunitake, Langmuir 14, 4559-4565 (1998). 90 Z. L. Wang, Journal of Physical Chemistry B 104, 1153-1175 (2000). 91 L. A. Bendersky and F. W. Gayle, Journal of Research of the National Institute of Standards and Technology 106, 997-1012 (2001). 92 Z. R. Dai, J. L. Gole, J. D. Stout, and Z. L. Wang, Journal of Physical Chemistry B 106, 1274-1279 (2002). 93 A. Taleb, C. Petit, and M. P. Pileni, Chemistry of Materials 9, 950-959 (1997). 94 J. R. Tesmer and M. Nastasi, Handbook of modern ion beam materials analysis (MRS, Pittsburgh, USA, 1995). 95 G. Binnig and H. Rohrer, Reviews of Modern Physics 59, 615-625 (1987).
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Nanotechnology-Enabled Sensors
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Kourosh Kalantar-zadeh RMIT Univers
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Acknowledgments We have been fortun
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viii Contents Chapter 3: Transducti
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x Contents 5.7.1 Scanning Electron
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xii Contents 7.5 Nano-sensors based
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2 Chapter 1: Introduction Nobel lau
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4 Chapter 1: Introduction Fig. 1.2
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6 Chapter 1: Introduction ensure th
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8 Chapter 1: Introduction ments, th
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10 Chapter 1: Introduction aim is t
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12 Chapter 1: Introduction Referenc
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14 Chapter 2: Sensor Characteristic
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64 Chapter 3: Transduction Platform
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100 Chapter 3: Transduction Platfor
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136 Chapter 4: Nano Fabrication and
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212 Chapter 5: Characterization Tec
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This is the dispersion relation for
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6.4 Phonons in Low Dimensional Stru
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335 vibrational degrees of freedom
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337 ing ballistic transport of elec
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339 Fig. 6.36 Nanoresonators made o
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6.5 Nanotechnology Enabled Mechanic
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6.6 Nanotechnology Enabled Optical
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6.7 Magnetically Engineered Spintro
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ferromagnetic haematite (a form of
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References 365 21 E. Comini, G. Fag
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References 367 58 D. E. Williams an
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References 369 96 J. J. Shi, Y. F.
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Chapter 7: Organic Nanotechnology E
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7.2 Surface Interactions 373 can be
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7.2 Surface Interactions 375 Carbox
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7.2 Surface Interactions 377 Fig. 7
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7.2 Surface Interactions 379 There
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Fig. 7.12 The schematic of physical
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Fig. 7.13 Formation of SAMs. 7.2 Su
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7.2 Surface Interactions 385 ple, t
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7.3 Surface Materials and Surface M
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7.4 Proteins in Nanotechnology Enab
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7.4.4 Using Proteins as Nanodevices
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Fig. 7.36 The general structure of
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+ 7.4 Proteins in Nanotechnology En
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7.5 Nano-sensors based on Nucleotid
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Fig. 7.57 The structure of DNA stra
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7.6 Sensors Based on Molecules with
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7.6 Sensors Based on Molecules with
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7.8 Biomagnetic Sensors 7.8 Biomagn
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7.9 Summary 471 metal oxides, carbo
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References 473 19 T. Kunitake, Ange
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63 J. X. Huang, S. Virji, B. H. Wei
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References 477 105 M. Plomer, G. G.
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References 479 145 R. F. Service, S
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7.8 References 481 185 J. Wang, D.
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Remote plasma enhanced CVD (RPECVD)
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Thin film equivalent circuit ... 32
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Optical waveguides ................
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Semiconductor-semiconductor junctio
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About the Authors Dr. Kourosh Kalan
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