The 3rd edition of this textbook offers clear explanations of optical spectroscopic phenomena and shows how spectroscopic techniques are used in modern chemistry, biochemistry and biophysics. Topics included are: electronic and vibrational absorption fluorescence symmetry operations and normal-mode calculations  electron transfer from excited molecules energy transfer exciton interactions electronic and vibrational circular dichroism coherence and dephasing ultrafast pump-probe and photon-echo spectroscopy single-molecule and fluorescence-correlation spectroscopy Raman scattering multiphoton absorption quantum optics and non-linear optics entropy changes during photoexcitation electronic and vibrational Stark effects  studies of fast processes in single molecules two-dimensional electronic and vibrational spectroscopy This revised and updated edition provides expanded discussions of laser spectroscopy, crystal symmetry, birefringence, non-linear optics, solar cells and light-emitting diodes. The explanations are sufficiently thorough and detailed to be useful for researchers, graduate students and advanced undergraduates in chemistry, biochemistry and biophysics. They are based on time-dependent quantum mechanics, but are developed from first principles so that they can be understood by readers with little prior training in the field. Additional topics and highlights are presented in special boxes in the text. The book is richly illustrated with color figures throughout. Each chapter ends with a section of questions for self-examination. 

Photocatalysis is considered by many as the most promising solution for energy and environment problems. Among all the photocatalysts available, titanium dioxide remains one of the most studied for decades. Reducing its bandgap via doping is crucial to harvest visible-light, which accounts for 48% of the total solar energy. In addition, it is very important to keep the particle size small to avoid recombination of the photo-generated electrons and holes. In this book, nano-scaled metal and / or non-metal elements have been used as dopants to modify the electronic structure of TiO2. X-ray diffraction patterns (XRD), Raman spectroscopy, UV-Vis diffuse reflectance spectroscopy (UV-DRS), Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), transmission electron microscopy (TEM) and X-ray photoelectron spectroscopy (XPS) have been used to obtain detailed information of the crystal structure, light-absorbing property, organic remains, particle appearance, size distribution and elemental compositions, respectively. Preliminary data indicates that the electronic structure of TiO2 has been effectively reduced to render visible-light reactivity.