Morphology and plasmonic properties of self-organized arrays of ...

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112 BIBLIOGRAPHY[74] Prashant K. Jain and Mostafa A. El-Sayed. Plasmonic coupling in noble metalnanostructures. Chem. Phys. Lett., 487:153, 2010.[75] A. Taleb, V. Russier, A. Courty, and M. P. Pileni. Collective optical propertiesof silver nanoparticles organized in two-dimensional superlattices. Phys. Rev. B,59:13350, 1999.[76] L. L. Zhao, K. L. Kelly, and G. C. Schatz. The extinction spectra of silver nanoparticlearrays: Influence of array structure on plasmon resonance wavelength and width.J. Phys. Chem. B, 107:7343, 2003.[77] Christy L. Haynes, Adam D. McFarland, LinLin Zhao, Richard P. Van Duyne,George C. Schatz, Linda Gunnarsson, Juris Prikulis, Bengt Kasemo, and MikaelKäll. Nanoparticle optics: The importance of radiative dipole coupling in twodimensionalnanoparticle arrays. J. Phys. Chem. B, 107:7337, 2003.[78] Erin M. Hicks, Shengli Zou, George C. Schatz, Kenneth G. Spears, Richard P.Van Duyne, Linda Gunnarsson, Tomas Rindzevicius, Bengt Kasemo, and MikaelKäll. Controlling plasmon line shapes through diffractive coupling in linear arraysof cylindrical nanoparticles fabricated by electron beam lithography. Nano Lett.,5:1065, 2005.[79] Luis M. Liz-Marzán. Tailoring surface plasmons through the morphology and assemblyof metal nanoparticles. Langmuir, 22:32, 2006.[80] S. K. Ghosh and T. Pal. Interparticle coupling effect on the surface plasmon resonanceof gold nanoparticles: From theory to applications. Chem. Rev., 107:4797,2007.[81] T. W. H. Oates, A. Keller, S. Faksko, and A. Mücklich. Aligned silver nanoparticleson rippled silicon templates exhibiting anisotropic plasmon absorption. Plasmonics,2:47, 2007.[82] StéphanieVial, IsabelPastoriza-Santos, JorgePérez-Juste, andLuisM.Liz-Marzán.Plasmon coupling in layer-by-layer assembled gold nanorod films. Langmuir,23:4606, 2007.[83] Fredrik Westerlund and Thomas Björnholm. Directed assembly of gold nanoparticles.Curr. Opin. Coll. Interf., 14:126, 2009.[84] I. Romero and F. J. García de Abajo. Anisotropy and particle-size effects in nanostructuredplasmonic metamaterials. Opt. Expr., 17:22010, 2009.[85] M. Quinten, A. Leitner, J. R. Krenn, and F. R. Aussenegg. Electromagnetic energytransport via linear chains of silver nanoparticles. Opt. Lett., 23:1331, 1998.[86] Mark L. Brongersma, John W. Hartman, and Harry A. Atwater. Electromagneticenergy transfer and switching in nanoparticle chain arrays below the diffractionlimit. Phys. Rev. B, 62:R16356, 2000.[87] H. Ko, S. Singamaneni, and V. V. Tsukruk. Nanostructured surfaces and assembliesas SERS media. Small, 4:1576, 2008.
BIBLIOGRAPHY 113[88] C. Petit, , and M. P. Pileni. Cobalt nanosized particles organized in a 2D superlattice:Synthesis, characterization, and magnetic properties. J. Phys. Chem. B,103:1805, 1999.[89] M. P. Pileni. Nanocrystal self-assemblies: Fabrication and collective properties. J.Phys. Chem. B, 105:3358, 2001.[90] N.Shukla, ErikB.Svedberg, andJ.Ell. Longrangeorderingofself-assembledmonolayersof FePt nanoparticles on modified substrates. Surf. Coat. Tech., 201:3810,2006.[91] Takami Shimizu, Toshiharu Teranishi, Satoshi Hasegawa, and Mikio Miyake. Sizeevolution of alkanethiol-protected gold nanoparticles by heat treatment in the solidstate. J. Phys. Chem. B, 107:2719, 2003.[92] David D. Evanoff and George Chumanov. Synthesis and optical properties of silvernanoparticles and arrays. ChemPhysChem, 6:1221, 2005.[93] Catherine J. Murphy, Tapan K. Sau, Anand M. Gole, Christopher J. Orendorff,Jinxin Gao, Linfeng Gou, Simona E. Hunyadi, and Tan Li. Anisotropic metalnanoparticles: Synthesis, assembly, and optical applications. J. Phys. Chem. B,109:13857, 2005.[94] FranklinKim, SerenaKwan, JenniferAkana, andPeidongYang. Langmuir-Blodgettnanorod assembly. Journal of the American Chemical Society, 123:4360, 2001.[95] Sihai Chen, Zhiyong Fan, and David L. Carroll. Silver nanodisks: Synthesis, characterization,and self-assembly. J. Phys. Chem. B, 106:10777, 2002.[96] A. N. Lagarkov and A. K. Sarychev. Electromagnetic properties of compositescontaining elongated conducting inclusions. Phys. Rev. B, 53:6318, 1996.[97] Rachel K. Smith, Penelope A. Lewis, and Paul S. Weiss. Patterning self-assembledmonolayers. Progr. Surf. Sci., 75:1, 2004.[98] M. Geissler and Y. Xia. Patterning: Principles and some new developments. Adv.Mat., 16:1249, 2004.[99] Xing Ling, Xin Zhu, Jin Zhang, Tao Zhu, Manhong Liu, Lianming Tong, and ZhongfanLiu. Reproducible patterning of single Au nanoparticles on silicon substrates byscanning probe oxidation and self-assembly. J. Phys. Chem. B, 109:2657, 2005.[100] Shantang Liu, Rivka Maoz, and Jacob Sagiv. Planned nanostructures of colloidalgold via self-assembly on hierarchically assembled organic bilayer template patternswith in-situ generated terminal amino functionality. Nano Letters, 4:845, 2004.[101] Nisha Shukla, Erik B. Svedberg, and John Ell. FePt nanoparticle adsorption on achemically patterned silicon-gold substrate. Surf. Coat. Tech., 201:1256, 2006.[102] Joanna Aizenberg, Andrew J. Black, and George M. Whitesides. Controlling localdisorder in self-assembled monolayers by patterning the topography of their metallicsupports. Nature, 394:868, 1998.
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Università degli studi di GenovaFa
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4 CONTENTS5.2.2 Optical anisotropy
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6 Introductionconfining the EM ener
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8 Introduction
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10 CHAPTER 1. THEORYEλBkFigure 1.1
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12 CHAPTER 1. THEORYfrom which, sep
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14 CHAPTER 1. THEORY≈ ω 0 like
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16 CHAPTER 1. THEORYε 1 (λ) = N 2
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18 CHAPTER 1. THEORYThe correspondi
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20 CHAPTER 1. THEORYso the induced
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22 CHAPTER 1. THEORYε MG −ε aε
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24 CHAPTER 1. THEORYUV range, this
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26 CHAPTER 1. THEORYwhich is called
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28 CHAPTER 1. THEORYwhere Γ 0 = v
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30 CHAPTER 1. THEORYpoints of the c
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32 CHAPTER 1. THEORYand then monoto
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34 CHAPTER 1. THEORYposition, has t
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36 CHAPTER 1. THEORYfieldorequivale
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38 CHAPTER 1. THEORY
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40 CHAPTER 2. EXPERIMENTAL METHODSt
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44 CHAPTER 2. EXPERIMENTAL METHODS2
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46 CHAPTER 2. EXPERIMENTAL METHODSs
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[001][100]50 CHAPTER 3. SELF-ORGANI
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52 CHAPTER 3. SELF-ORGANIZED NPS AR
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Page 62 and 63: 62 CHAPTER 4. SELF-ORGANIZED NPS AR
Page 76 and 77: 76 CHAPTER 5. MODELLING AND ANALYSI
Page 98 and 99: 98 CHAPTER 6. COMPOSITE MEDIA BASED
Page 100 and 101: 100 CHAPTER 6. COMPOSITE MEDIA BASE
Page 102 and 103: 102 CHAPTER 6. COMPOSITE MEDIA BASE
Page 104 and 105: 104 Conclusionsparticular cases of
Page 106 and 107: 106 Acknowledgements
Page 108 and 109: 108 BIBLIOGRAPHY[14] Shouheng Sun,
Page 110 and 111: 110 BIBLIOGRAPHY[44] Q A Pankhurst,
Page 114 and 115: 114 BIBLIOGRAPHY[103] Tobias Kraus,
Page 116 and 117: 116 BIBLIOGRAPHY[137] F. Brouers, J
Page 118 and 119: 118 BIBLIOGRAPHY[169] Christy L. Ha
Page 120 and 121: 120 BIBLIOGRAPHY[201] G. Baldacchin
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