Linked e-resources
Details
Table of Contents
Supervisor's Foreword; Acknowledgments; Contents; 1 Introduction: Optically-Mediated Particle Manipulation with High Throughput; References; 2 Electrokinetic Forces in Inhomogeneous Fields; 2.1 Electrophoresis and Dielectrophoresis; 2.2 Dielectrophoretic Force Calculation; 2.3 Clausius-Mossotti Factor; 2.4 Generalization of DEP for Large Objects and Continuous Media: Multipoles and Polarization Force Density; References; 3 Electric Fields and Their Detection in Photorefractive Crystals; 3.1 Optical Induction of Virtual Electrodes
3.2 Photorefractive Crystals and Kukhtarev's Band Transport Model3.3 Internal Fields for Dielectrophoretic Trapping; 3.4 Bulk Photovoltaic Effect; 3.5 Visualization of Internal Electric Fields: Pockels Effect; 3.5.1 Optical Activity and Pockels Effect in BSO; 3.6 Measurement Techniques for the Evaluation of Photorefractive Media; 3.6.1 Diffraction Efficiency; 3.6.2 Zernike Phase Contrast; 3.6.3 Digital Holographic Microscopy (DHM); References; 4 Quantitative Investigation of Photorefractive Substrate Materials; 4.1 Highly Reduced Iron-Doped Lithium Niobate (LiNbO3)
4.1.1 General Properties of LiNbO34.1.2 Sample Preparation and Reduction Treatment; 4.1.3 Measurement of Charge Transport Parameters; 4.1.4 Electric Field Structure at High Modulation Depths; 4.2 Bismuth Silicon Oxide (BSO); 4.2.1 Photoconductivity and Real-Time Induction of Space-Charge Fields; 4.2.2 Temporal Electric Field Response of BSO; 4.2.3 AC Response of Internal Space-Charge Fields in BSO; 4.2.4 Electric Field Structure and Phase-Shift Inside BSO; References; 5 Optically-Induced Dielectrophoretic Particle Trapping; 5.1 Bismuth Silicon Oxide (BSO); 5.2 Lithium Niobate (LiNbO3)
5.3 Measurement and Anisotropy of Dielectrophoretic Forces in POT5.4 Surface Discharge Model; References; 6 Optofluidic Applications for Photorefractive Optoelectronic Tweezers; 6.1 Multiplexing and Switching of Virtual Electrodes; 6.2 Charge Sensing and Particle Trapping on z-Cut Lithium Niobate Samples; 6.3 Fabrication of Polymer Gratings on Photorefractive LiNbO3; 6.3.1 Thickness Measurement of Spin-Coated PDMS Layers; 6.3.2 Optically-Induced Structuring of PDMS Layers; 6.4 Optofluidic Router; 6.4.1 Droplet Generator Design; 6.4.2 Optically-Induced Routing of Air and Liquid Droplets
3.2 Photorefractive Crystals and Kukhtarev's Band Transport Model3.3 Internal Fields for Dielectrophoretic Trapping; 3.4 Bulk Photovoltaic Effect; 3.5 Visualization of Internal Electric Fields: Pockels Effect; 3.5.1 Optical Activity and Pockels Effect in BSO; 3.6 Measurement Techniques for the Evaluation of Photorefractive Media; 3.6.1 Diffraction Efficiency; 3.6.2 Zernike Phase Contrast; 3.6.3 Digital Holographic Microscopy (DHM); References; 4 Quantitative Investigation of Photorefractive Substrate Materials; 4.1 Highly Reduced Iron-Doped Lithium Niobate (LiNbO3)
4.1.1 General Properties of LiNbO34.1.2 Sample Preparation and Reduction Treatment; 4.1.3 Measurement of Charge Transport Parameters; 4.1.4 Electric Field Structure at High Modulation Depths; 4.2 Bismuth Silicon Oxide (BSO); 4.2.1 Photoconductivity and Real-Time Induction of Space-Charge Fields; 4.2.2 Temporal Electric Field Response of BSO; 4.2.3 AC Response of Internal Space-Charge Fields in BSO; 4.2.4 Electric Field Structure and Phase-Shift Inside BSO; References; 5 Optically-Induced Dielectrophoretic Particle Trapping; 5.1 Bismuth Silicon Oxide (BSO); 5.2 Lithium Niobate (LiNbO3)
5.3 Measurement and Anisotropy of Dielectrophoretic Forces in POT5.4 Surface Discharge Model; References; 6 Optofluidic Applications for Photorefractive Optoelectronic Tweezers; 6.1 Multiplexing and Switching of Virtual Electrodes; 6.2 Charge Sensing and Particle Trapping on z-Cut Lithium Niobate Samples; 6.3 Fabrication of Polymer Gratings on Photorefractive LiNbO3; 6.3.1 Thickness Measurement of Spin-Coated PDMS Layers; 6.3.2 Optically-Induced Structuring of PDMS Layers; 6.4 Optofluidic Router; 6.4.1 Droplet Generator Design; 6.4.2 Optically-Induced Routing of Air and Liquid Droplets