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Colour and the Optical Properties of Materials carefully
introduces the science behind the subject, along with many modern
and cutting-edge applications, chosen to appeal to today's
students. For science students, it provides a broad introduction to
the subject and the many applications of colour. To more applied
students, such as engineering and arts students, it provides the
essential scientific background to colour and the many
applications.
New to this Edition:
The chapter framework of the first edition will be retained,
with each chapter being substantially rewritten and some material
would be relocated. Some chapters will be rewritten in a clearer
fashion, e.g. There have been no significant advances in the
understanding of rainbows recently, but the text could be clarified
and improved.
Colour has been an important attribute of many nano-particle
containing systems, such as quantum dots. This aspect will be
included, e.g. the colour of gold ruby glass, described in Chapter
5 as part of scattering phenomena now is better treated in terms of
gold nanoparticles and surface plasmons. This would probably be
transferred to Chapter 10 and considered in tandem with the colour
of metals such as copper, silver and gold. A similar state of
affairs applies to silver nanoparticles and polychromic glass.
Some chapters will include extensive new material, e.g. Chapter
8, colours due to molecular processes [organic LEDs etc], and
Chapter 12, Displays, [touch screen technologies].
For all chapters it would be intended to take into account the
current scientific literature up to the time of submission -
say up to the end of 2009. The end of chapter Further Reading
sections would reflect this up-to-date overview.
The end of chapter problems will be strengthened and
expanded.
Auteur
Richard J. D. Tilley, D. Sc, Ph. D, is Emeritus Professor in the School of Engineering at the University of Cardiff, Wales, U.K. He has published extensively in the area of solid-state materials science, including 180 papers, fifteen book chapters and numerous book reviews.
Résumé
Colour and the Optical Properties of Materials carefully introduces the science behind the subject, along with many modern and cutting-edge applications, chosen to appeal to today's students. For science students, it provides a broad introduction to the subject and the many applications of colour. To more applied students, such as engineering and arts students, it provides the essential scientific background to colour and the many applications.
New to this Edition:
Contenu
Preface.
1 Light and Colour.
1.1 Colour and light.
1.2 Colour and energy.
1.3 Light waves.
1.4 Interference.
1.5 Light waves and colour.
1.6 Black body radiation and incandescence.
1.7 The colour of incandescent objects.
1.8 Photons.
1.9 Lamps and lasers.
1.10 Vision.
1.11 Colour perception.
1.12 Additive coloration.
1.13 The interaction of light with a material.
1.14 Subtractive coloration.
1.15 Electronic paper.
1.16 Appearance and transparency.
Appendix 1.1 Definitions, units and conversion factors.
Further reading.
2 Colours due to Refraction and Dispersion.
2.1 Refraction and the refractive index of a material.
2.2 Total internal reflection.
2.3 Refractive index and polarisability.
2.4 Refractive index and density.
2.5 Invisible animals, GRINS and mirages.
2.6 Dispersion and colours produced by dispersion.
2.7 Rainbows and halos.
2.8 Halos.
2.9 Fibre optics.
2.10 Negative refractive index materials.
Further reading.
3 The Production of Colour by Reflection.
3.1 Reflection from a single surface.
3.2 Interference at a single thin film in air.
3.3 The colour of a single thin film in air.
3.4 The reflectivity of a single thin film in air.
3.5 The colour of a single thin film on a substrate.
3.6 The reflectivity of a single thin film on a substrate.
3.7 Low-reflection and high-reflection films.
3.8 Multiple thin films.
3.9 Fibre Bragg Gratings.
3.10 Smart windows.
3.11 Photonic engineering in nature.
3.12 Further reading.
3.13 Problems and exercises.
Appendix 3.1 The colour of a thin film in white light.
Further Reading.
4 Polarisation and crystals.
4.1 Polarisation of light.
4.2 Polarisation by reflection.
4.3 Polars.
4.4 Crystal symmetry and refractive index.
4.5 Double refraction: calcite as an example.
4.6 The description of double refraction effects.
4.7 Colour produced by polarisation and birefringence.
4.8 Pleochroism and dichroism.
4.9 Nonlinear effects.
4.10 Frequency matching and phase matching.
4.11 More on second harmonic generation.
4.12 Optical activity.
4.13 Liquid crystals.
Further reading.
5 Colour due to Scattering.
5.1 Scattering and extinction.
5.2 Tyndall blue and Rayleigh scattering.
5.3 Blue skies, red sunsets.
5.4 Scattering and polarisation.
5.5 Mie scattering.
5.6 Blue eyes and some blue feathers.
5.7 Paints, sunscreens and related matters.
5.8 Multiple scattering.
5.9 Gold sols and ruby glass.
5.10 The Lycurgus Cup.
Further reading.
6 Colour due to Diffraction.
6.1 Diffraction and colour production by a slit.
6.2 Diffraction and colour production by a rectangular aperture.
6.3 Diffraction and colour production by a circular aperture.
6.4 The diffraction limit of optical instruments.
6.5 Colour production by linear diffraction gratings.
6.6 Two-dimensional gratings.
6.7 Estimation of the wavelength of light by diffraction.
6.8 Diffraction by crystals and crystal-like structures.
6.9 Disordered diffraction gratings.
6.10 Diffraction by sub-wavelength structures.
6.11 Holograms.
Further reading.
7 Colour from Atoms and Ions.
7.1 The spectra of atoms and ions. 7.2 Terms and levels.</...