An Introduction to the Optical Spectroscopy of Inorganic Solids (eBook)

Jose Solé, Department of Material Science, University of Madrid, Spain. Luis Bausa, Department of Material Science, University of Madrid, Spain. Daniel Jaque, Department of Material Science, University of Madrid, Spain.

PREFACE.

ACKNOWLEDGEMENTS.

SOME PHYSICAL CONSTANTS OF INTEREST IN SPECTROSCOPY.

I FUNDAMENTALS.

I.1 Origin of the Spectroscopy.

I.2 Electromagnetic Spectrum. Optical Spectroscopy.

I.3 Absorption. The Spectrophotometer.

I.4 Luminescence. The Spectrofluorimeter. Time resolved
luminescence.

I.5 Scattering. The Raman effect.

I.6 Advanced topic: The Fourier Transform Spectrophotometer.

Exercises.

II LIGHT SOURCES.

II.1 Introduction.

II.2 Lamps.

II.3 The Laser. Basic principles.

II.4 Types of Lasers.

II.5 Tunability of laser radiation. The Optical Parametric
Oscillator.

II.6 Advanced Topic:1) Site Selective Spectroscopy. 2) Excited
State Absorption.

Exercises.

III MONOCHROMATORS AND DETECTORS.

III.1 Introduction.

III.2 Monochromators.

III.3 Types of detectors. Basic parameters.

III.4 The Photomultiplier.

III.5 Signal/noise ratio optimisation.

III.6 Detection of pulses.

III.7 Advanced Topic: Detection of very fast pulses; The Streak
Camera; The Correlator.

Exercises.

IV. OPTICAL TRANSPARENCY OF SOLIDS.

IV.1 Introduction.

IV.2 Optical magnitudes and the dielectric constant.

IV.3The Lorentz oscillator.

IV.4 Metals.

IV.5 Semiconductors and insulators.

IV.6 Spectral shape of the fundamental absorption edge.

IV.7 Excitons.

IV.8 Advanced topic: The colour of metals.

Exercises.

V. OPTICALLY ACTIVE CENTRES.

V.1 Introduction.

V.2 Static interaction. The crystalline field.

V.3 Band intensities. The oscillator strength.

V.4 Dynamic interaction. The coordinate configuration
diagram.

V.5 Band shape. The Huang-Rhys factor.

V.6 Non radiative transitions. Energy transfer.

V.7 Advanced topic: Determination of quantum efficiencies.

Exercises.

VI. APPLICATIONS: RARE EARTH AND TRANSITION METAL IONS, COLOUR
CENTERS.

VI.1 Introduction.

VI.2 Trivalent rare earth ions. Diagram of Dieke.

VI.3 Non radiative transitions in rare earth ions; The "energy
gap" law.

VI.4 Transition metal ions. Tanabe- Sugano diagrams.

VI.5 Colour centres.

VI.6 Advanced topic: 1) The Judd and Ofelt method. 2) Optical
cooling of solids.

Exercises.

VII. GROUP THEORY AND SPECTROSCOPY.

VII.1 Introduction.

VII.2 Symmetry operations and classes.

VII.3 Representations. The character table.

VII.4 Reduction in symmetry and splitting of energy levels.

VII.5 Selection rules for optical transitions.

VII.6 Illustrative examples.

VII.7 Advanced topic: Applications to optical transitions of
Kramers ions.

Exercises.

APPENDICES.

APPENDIX A1.- The joint density of states.

APPENDIX A2.- Effect of an octahedral field on a valence
electron d¯1.

APPENDIX A3.- Calculation of the spontaneous emission
probability by the Einstein thermodynamic treatment.

APPENDIX A4.- Determination of the Smakula´s formula.

INDEX.

"This is a useful book for an undergraduate or an early-stage
postgraduate course in spectroscopy." (Reviews, June 2008)

"[allows] students with a background in quantum physics and
solid state physics, to interpret simple optical spectra...and
obtain knowledge of the main instrumentation used in this field."
(Chimie Nouvelle, March 2007)