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A comprehensive and systematic treatment of our current understanding of the microfluidic technique and its advantages in the controllable fabrication of advanced functional polymeric materials. Introducing and summarizing recent advances and achievements in the field, the authors cover the design and fabrication of microfluidic devices, the fundamentals and strategies for controllable microfluidic generation of multiphase liquid systems, and the use of these liquid systems with an elaborate combination of their structures and compositions for generating novel polymer materials, such as…mehr
A comprehensive and systematic treatment of our current understanding of the microfluidic technique and its advantages in the controllable fabrication of advanced functional polymeric materials. Introducing and summarizing recent advances and achievements in the field, the authors cover the design and fabrication of microfluidic devices, the fundamentals and strategies for controllable microfluidic generation of multiphase liquid systems, and the use of these liquid systems with an elaborate combination of their structures and compositions for generating novel polymer materials, such as microcapsules, microfibers, valves, and membranes. Clear diagrams and illustrations throughout the text make the relevant theory and technologies more readily accessible. The result is a specialist reference for materials scientists, organic, polymer and physical chemists, and chemical engineers.
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Autorenporträt
Professor Liang-Yin Chu is the School Dean of Chemical Engineering at Sichuan University in Chengdu, China. Professor Chu has received numerous honours and awards including the National Natural Science Award nominated by the Ministry of Education of China (2003), Distinguished Young Scholar issued by the National Natural Science Foundation of China (2008), Distinguished Professor of Chang Jiang Scholars Program issued by the Ministry of Education (2009), Te-Pang Hou Chemical Science and Technology Innovation Award issued by the Chemical Industry and Engineering Society of China (2013). He has authored/coauthored more than 400 papers, 37 patents, 14 book chapters and four books. Currently, Professor Chu directs a talented research group with a diverse and interdisciplinary focus on the development of advanced functional materials, microfluidics, membranes and biomaterials. Dr. Wei Wang is an associate professor of School of Chemical Engineering at Sichuan University in Chengdu, China. His research mainly focuses on functional materials, microfluidics, and interfacial sciences. He has authored and co-authored 76 papers that published in peer-reviewed journals. He was awarded many honours and awards, including the Emerging Investigator 2014 of Lab on a Chip (The Royal Society of Chemistry), Materials Horizons Paper Prize at the 8th Global Chinese Chemical Engineers Symposium (2016), and the Excellent Paper Award issued by the Organization Committee of the 3rd Asian Conference on Colloids and Interface Science (2009).
Inhaltsangabe
1. Introduction2. Shear-induced generation of controllable multiple emulsions in microfluidic devices3. Wetting-induced generation of controllable multiple emulsions in microfluidic devices4. Microfluidic fabrication of monodisperse solid microparticles4.1 Stimuli-responsive microspheres for sensing and actuating4.2 Smart microspheres for Pb2+ adsorption and separation5. Microfluidic fabrication of monodisperse porous microparticles5.1 Thermo-responsive porous microparticles with tunable response behaviors5.2 Thermo-responsive microparticles with open-celled porous structure for fast response6. Microfluidic fabrication of uniform hierarchical porous microparticles for separation7. Microfluidic fabrication of monodisperse hollow microcapsules for controlled release7.1 Glucose-responsive microcapsules for controlled release of insulin7.2 Multi-stimuli-responsive microcapsules for adjustable controlled-release8. Microfluidic fabrication of monodisperse core-shell microcapsules for burst release8.1 Smart microcapsules for thermo-triggered burst release8.2 Smart microcapsules for pH-responsive burst release8.3 Smart microcapsules for K+-responsive burst release9. Microfluidic fabrication of monodisperse hole-shell microparticles for controlled capture10. Microfluidic fabrication of controllable multicompartmental microparticles10.1 Multi-core/shell microparticles for co-encapsulation and synergistic release10.2 Trojan-Horse-like microparticles for co-delivery and programmed release11. Microfluidic fabrication of functional microfibers with controllable internals11.1 Peapod-like microfibers for controllable encapsulation11.2 Spider-silk-like microfibers for 3D assembly and water collection12. Microfluidic fabrication of membrane-in-a-chip with self-regulated permeability for detection13. Microfluidic fabrication of microvalve-in-a-chip13.1 Smart microvalve-in-a-chip with thermostatic control for cell culture13.2 Smart microvalve-in-a-chip with ultra-sensitivity for real-time detection14. Conclusions and PerspectiveIndex
1. Introduction2. Shear-induced generation of controllable multiple emulsions in microfluidic devices3. Wetting-induced generation of controllable multiple emulsions in microfluidic devices4. Microfluidic fabrication of monodisperse solid microparticles4.1 Stimuli-responsive microspheres for sensing and actuating4.2 Smart microspheres for Pb2+ adsorption and separation5. Microfluidic fabrication of monodisperse porous microparticles5.1 Thermo-responsive porous microparticles with tunable response behaviors5.2 Thermo-responsive microparticles with open-celled porous structure for fast response6. Microfluidic fabrication of uniform hierarchical porous microparticles for separation7. Microfluidic fabrication of monodisperse hollow microcapsules for controlled release7.1 Glucose-responsive microcapsules for controlled release of insulin7.2 Multi-stimuli-responsive microcapsules for adjustable controlled-release8. Microfluidic fabrication of monodisperse core-shell microcapsules for burst release8.1 Smart microcapsules for thermo-triggered burst release8.2 Smart microcapsules for pH-responsive burst release8.3 Smart microcapsules for K+-responsive burst release9. Microfluidic fabrication of monodisperse hole-shell microparticles for controlled capture10. Microfluidic fabrication of controllable multicompartmental microparticles10.1 Multi-core/shell microparticles for co-encapsulation and synergistic release10.2 Trojan-Horse-like microparticles for co-delivery and programmed release11. Microfluidic fabrication of functional microfibers with controllable internals11.1 Peapod-like microfibers for controllable encapsulation11.2 Spider-silk-like microfibers for 3D assembly and water collection12. Microfluidic fabrication of membrane-in-a-chip with self-regulated permeability for detection13. Microfluidic fabrication of microvalve-in-a-chip13.1 Smart microvalve-in-a-chip with thermostatic control for cell culture13.2 Smart microvalve-in-a-chip with ultra-sensitivity for real-time detection14. Conclusions and PerspectiveIndex
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