288 pages | 119 B/W Illus.
Remarkable developments in the spectroscopy field regarding ultrashort pulse generation have led to the possibility of producing light pulses ranging from 50 to5 fs and frequency tunable from the near infrared to the ultraviolet range. Such pulses enable us to follow the coupling of vibrational motion to the electronic transitions in molecules and solids in real time.
Detailing these advanced developments, as well as the fundamental methods and tools of vibrational spectroscopy, Coherent Vibrational Dynamics providesresearchers and students with a uniquely comprehensive resource. With the contributions of pioneering scientists, this seminal volume –
· Outlines the principles and tools used on time-domain vibrational spectroscopy and provides a general introduction to the subject of coherent phonons
· Describes the modern methods for tunable ultrashort pulse generation from infrared to visible-UV
· Reviews coherent vibrational dynamics in small molecules in liquids (hydrogen bonds), and in carbon based conjugated materials (polyenes, carotenoids, and semiconducting polymers)
· Explores phonon dynamics in semiconductors (bulk and heterostructures) and in quasi-one-dimensional systems
Supplemented with a great number of references, and covering fundamental as well advanced topics, this text provides a valuable reference for both graduate students and senior researchers investigating materials in physics, chemistry, and biology. It is also an excellent starting point for those who want to pursue research in the field of ultrafast optics and spectroscopy.
Time Domain Vibrational Spectroscopy: Principle
and Experimental Tools,G. Cerullo and C. Manzoni
Coherent Dynamics of Hydrogen Bonds in Liquids Studied by Femtosecond Vibrational Spectroscopy,T. Elsaesser
Coherent Phonon Dynamics in π-Conjugated Chains,G. Lanzani
Coherent Phonons in Bulk and Low-Dimensional Semiconductors,M. Först and T. Dekorsy
Coherent Dynamics of Halogen Molecules in Rare Gas Solids,M. Gühr
Coherent Vibrational Dynamics of Exciton Self-Trapping in Quasi-One-Dimensional Systems,S.L. Dexheimer