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200 10$aHomer and classical philology /$fFriedrich Nietzsche; edited by Oscar Levy; translated by J.M. Kennedy
210  1$a[Auckland, New Zealand] :$cThe Floating Press,$d[2013]
210  4$d©2013
215   $a1 online resource (26 p.)
300   $aDescription based upon print version of record.
327   $aTitle; Contents; Homer and Classical Philology; Endnotes
330   $aAlthough he later rose to prominence as an innovative and controversial philosopher whose ideas influenced everyone from existentialist thinkers to the Nazi movement, Friedrich Nietzsche was trained in philology and published his earliest works on that topic. This essay takes a look at the use of mythology and language in the ancient Greek poet's most important works, The Iliad and The Odyssey.
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200 10$aEn montagne Bourbonnaise $emoeurs et coutumes, superstitions et sorciers /$fAntonin Brisson
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210  4$d©2015
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327   $aPage de titre; Avant-propos; PREMIE?RE PARTIE - M?urs et coutumes; DEUXIE?ME PARTIE - La superstition et les sorciers; Les Panseurs; Les Gougneurs; Les Rebouteurs; Les me?decins de bestiaux; Le Jeteur de sorts; La Sorcie?re de Ce?ron; La Sorcie?re de Bussie?res; La Dormeuse de Lapalisse; Page de Copyright
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200 10$aSilicon photonics$b[electronic resource] $ean introduction /$fGraham T. Reed, Andrew P. Knights
210   $aChichester ;$aHoboken, NJ $cJohn Wiley$dc2004
215   $a1 online resource (277 p.)
300   $aDescription based upon print version of record.
311   $a0-470-87034-6 
320   $aIncludes bibliographical references and index.
327   $aSilicon Photonics; Contents; About the Authors; Foreword; Acknowledgements; 1 Fundamentals; 1.1 What is Phase?; 1.2 What is Polarisation?; 1.3 What is Interference?; 2 The Basics of Guided Waves; 2.1 The Ray Optics Approach to Describing Planar Waveguides; 2.2 Reflection Coefficients; 2.3 Phase of a Propagating Wave and its Wavevector; 2.4 Modes of a Planar Waveguide; 2.4.1 The Symmetrical Planar Waveguide; 2.4.2 The Asymmetrical Planar Waveguide; 2.4.3 Solving the Eigenvalue Equations for Symmetrical and Asymmetrical Waveguides; 2.4.4 Monomode Conditions; 2.4.5 Effective Index of a Mode
327   $a2.5 A Taste of Electromagnetic Theory2.6 Simplifying and Solving the Wave Equation; 2.7 Another Look at Propagation Constants; 2.8 Mode Profiles; 2.9 Confinement Factor; 2.10 The Goos-Ha?nchen Shift; 3 Characteristics of Optical Fibres for Communications; 3.1 The Structure of Optical Fibres; 3.2 Modes of an Optical Fibre; 3.2.1 Modes of a Step-index Fibre; 3.2.2 Modes of a Graded-index Fibre; 3.3 Numerical Aperture and Acceptance Angle; 3.4 Dispersion in Optical Fibres; 3.4.1 Intermodal Dispersion; 3.4.2 Intramodal Dispersion
327   $a3.5 Single-mode Fibres: Mode Profile, Mode-field Diameter, and Spot Size3.6 Normalised Frequency, Normalised Propagation Constant, and Cutoff Wavelength; References; 4 Silicon-on-Insulator (SOI) Photonics; 4.1 Introduction; 4.2 Silicon-on-Insulator Waveguides; 4.2.1 Modes of Two-dimensional Waveguides; 4.3 The Effective Index Method of Analysis; 4.4 Large Single-mode Rib Waveguides; 4.5 Refractive Index and Loss Coefficient in Optical Waveguides; 4.6 Contributions to Loss in an Optical Waveguide; 4.6.1 Scattering; 4.6.2 Absorption; 4.6.3 Radiation; 4.7 Coupling to the Optical Circuit
327   $a4.7.1 Grating Couplers4.7.2 Butt Coupling and End-fire Coupling; 4.7.3 Robust Coupling to Waveguides for Commercial Applications; 4.7.4 Measurement of Propagation Loss in Integrated Optical Waveguides; 4.8 Optical Modulation Mechanisms in Silicon; 4.8.1 Electric Field Effects; 4.8.2 Carrier Injection or Depletion; 4.8.3 The Thermo-optic Effect; 4.9 Other Advantages and Disadvantages of Silicon Photonics; References; 5 Fabrication of Silicon Waveguide Devices; 5.1 Silicon-on-Insulator (SOI); 5.1.1 Separation by IMplanted OXygen (SIMOX); 5.1.2 Bond and Etch-back SOI (BESOI)
327   $a5.1.3 Wafer Splitting (SmartCut(®) Process to Produce Unibond(®) Wafers)5.1.4 Silicon Epitaxial Growth; 5.1.5 Deciding on the SOI; 5.2 Fabrication of Surface Etched Features; 5.2.1 Photolithography; 5.2.2 Silicon Etching; 5.2.3 Critical Dimension Control; 5.3 Oxidation; 5.4 Formation of Submicron Silicon Waveguides; 5.4.1 Silicon Dioxide Thickness; 5.4.2 Surface and Interface Roughness; 5.4.3 Sidewall Roughness; 5.5 Silicon Doping; 5.5.1 Ion Implantation; 5.5.2 The Implantation System; 5.5.3 Implantation Parameters; 5.5.4 Dopant Activation and Drive-in; 5.6 Metallisation; 5.6.1 Via Formation
327   $a5.6.2 Metal Deposition
330   $aThe growing demand for instant and reliable communication means that photonic circuits are increasingly finding applications in optical communications systems. One of the prime candidates to provide satisfactory performance at low cost in the photonic circuit is silicon.  Whilst silicon photonics is less well developed as compared to some other material technologies, it is poised to make a serious impact on the telecommunications industry, as well as in many other applications, as other technologies fail to meet the yield/performance/cost trade-offs. Following a sympathetic tutorial approach, 
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606   $aPhotonics
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