Chapter 1Introduction Chapter 2Basic Theory of Nonlinear Optics 2.1Classical electromagnetic theory of nonlinear optics 2.1.1Measurement of nonlinear optical processes 2.1.2Nonlinearly induced polarization effect of optical media 2.1.3Tensor representation of nonlinear polarization 2.1.4Rotational symmetry of nonlinear polarizability tensor elements 2.1.5Time reversal symmetry of polarization rate 2.2Quantum theory and method of nonlinear optics 2.2.1Density matrix 2.2.2Timedependent density matrix 2.2.3The tensor and properties of the polarizability of the independent molecular system 2.2.4The tensor and properties of the polarizability of the molecular system with intermolecular interaction 2.2.5Resonanceenhanced polarizability 2.2.6Calculation method of nonlinear polarizability by higher order derivative 2.2.7Nonlinear polarizability by sumoverstate method 2.3Common nonlinear optical processes 2.3.1Second harmonic generation 2.3.2Sum frequency generation 2.3.3Raman amplification 2.3.4Fourwave mixing Chapter 3The Principle, Application and Imaging of CARS 3.1Principles of CARS 3.1.1Mechanism of CARS signal generation 3.1.2CARS optical configuration 3.2Biomedical imaging of CARS 3.3Materials imaging of CARS 3.3.1CARS image for porous carbon 3.3.2CARS image for graphene Chapter 4The Principle, Application and Imaging of SRS 4.1Principles of SRS 4.1.1Quantum theory of SRS 4.1.2Instrumentation of SRS 4.2Biomedical imaging 4.2.1SRS imaging of hela cells 4.2.2SRS detection and diagnosis of the boundary of glioma 4.2.3SRS imaging of laryngeal cancer 4.3Material composition analysis Chapter 5The Principle, Application and Imaging of SHG 5.1Principles of SHG 5.2Biomedical imaging of SHG 5.2.1Collagen 5.2.2SHG imaging for elastic arteries 5.2.3SHG imaging for snail Chapter 6The Principle, Application and Imaging of TPEF 6.1Principles of TPEF 6.1.1Twophoton absorption 6.1.2Design of strong TPA cross section 6.1.3Twophoton excited/emitted fluoresence 6.1.4TPEF optical configuration 6.2Biomedical imaging of TPEF 6.2.1TPEF and lifetime imaging for glioma 6.2.2TPEF and lifetime imaging for gastrointestinal cancer Chapter 7The Principle, Application and Imaging of STED 7.1Principles of STED 7.1.1Selection of excitation and loss laser types 7.1.2Selection of excitation and loss wavelengths 7.2Biomedical imaging of STED 7.2.1Nervous structure imaging 7.2.23D STED imaging Chapter 8PlasmonEnhanced Nonlinear Spectroscopy and Imagin 8.1Principles 8.1.1Plasmon 8.1.2Enhancement mechanism 8.2Application of surface plasmon enhanced nonlinear optical signals 8.2.1Surfaceplasmonenhanced CARS 8.2.2Surfaceplasmonenhanced TPEF 8.2.3Surfaceplasmonenhanced highorder harmonic wave generate Bibliography Acknowledgement Indexes |