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E-Book, Englisch, 603 Seiten, E-Book

Kureha / Suzuki Micro and Nano Gels

Synthesis, Characterization, Modelling, and Applications
1. Auflage 2026
ISBN: 978-3-527-85566-7
Verlag: Wiley-VCH
Format: PDF
 Kopierschutz: Adobe DRM (»Systemvoraussetzungen)

Synthesis, Characterization, Modelling, and Applications

E-Book, Englisch, 603 Seiten, E-Book

ISBN: 978-3-527-85566-7
Verlag: Wiley-VCH
Format: PDF
 Kopierschutz: Adobe DRM (»Systemvoraussetzungen)

covers innovative synthesis, characterization, application, and modeling strategies in the forefront of microgel/nanogels research.

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Autoren/Hrsg.

Kureha, Takuma
Suzuki, Daisuke

Weitere Infos & Material

Preface
 
PART ONE INTRODUCTION AND PERSPECTIVE
1 Soft Microgels and Nanogels from a Physico-Chemical Perspective
2 Perspective on the Translational Potential of Responsive Micro- and Nanogels
 
PART TWO SYNTHESIS
3 Amphiphilic Random Copolymer Micelles: Design, Self-Assembly, and Functional Materials
3.1 Introduction
3.2 Design and Synthesis of Amphiphilic Random Copolymers
3.3 Self-Assembly of Amphiphilic Random Copolymers
3.4 Self-Sorting and Co-Self-Assembly of Binary Mixtures
3.5 Self-Healing and Selectively Adhesive Hydrogels
3.6 Functional Nanoaggregates
3.7 Conclusion
 
4 Advances in Synthesis of Functional Colloidal Gels
4.1 Introduction
4.2 Template-Free Synthesis Methods
4.3 Template-Based Synthesis Methods
4.4 Conclusions
 
PART THREE CHARACTERIZATION
 
5 Polymeric Microgels: Insights from Light Scattering, Electron Microscopy, and Optical Superresolution Techniques
5.1 Outline
5.2 COMMON THERMOSENSITIVE PNIPAM MICROGELS
5.3 CHARACTERIZATION TECHNIQUES FOR MICROGELS
5.4 CASE STUDIES
5.5 CONCLUSIONS
 
6 Formation and Shear Yielding Dynamics of Poly(N-isopropylacrylamide) Based Colloidal Gels
6.1 Introduction
6.2 Single microgel properties
6.3 Criteria of colloidal gelation
6.4 Shear yielding behavior of dilute colloidal gels
6.5 Conclusions
 
7 Structural characterization of microgels by means of neutron scattering, reflectometry, and computer simulations
7.1 Softness
7.2 Principles of small-angle scattering
7.3 In silico microgels
7.4 Microgel architecture in dilute suspensions
7.5 Microgel architecture in concentrated suspensions
7.6 Determination of the microgel elastic moduli
7.7 Microgel architecture at the interface studied by neutron reflectometry
7.8 Final remarks and outlooks
 
8 Dynamic and direct visualization of the nanostructure and functions of microgels via high-speed atomic force microscopy
8.1 Introduction
8.2 Evaluation of the inhomogeneous nanostructure in microgels
8.3 Real-time visualization of the microgel function
8.4 Surface characterization of microgels using force?indentation curves
8.5 Outlook
 
9 The analysis of the dynamics of microgels and their assemblies using light scattering techniques
9.1 Introduction
9.2 Model Microgels
9.3 Dilute Concentration Region
9.4 Intermediate Concentration Region
9.5 High Concentration Region
9.6 Conclusions
 
10 Computer Simulations of Nano- and Microgel Systems
10.1 Introduction
10.2 Nano- and microgels at the mesoscale
10.3 Nano- and microgels at other scales
10.4 Outlook
 
11 Electrophoresis of micro/nano gels
11.1 Introduction
11.2 Brinkman-Debye-Bueche model
11.3 Electric potential distribution across a gel layer
11.4 Large gel particle with a planar core surface
11.5 Electrophoresis of a spherical gel
11.6 Electrophoretic mobility of a weakly charged spherical gel particle
11.7 Relaxation effect
11.8 pH-dependent electrophoretic mobility of a gel particle
11.9 Electrophoresis of a gel particle in a polymer gel medium
 
PART FOUR INTERFACE AND ASSEMBLY
 
12 Microgel Assembly: From Bulk Phases to Interfaces
12.1 Introduction
12.2 Microgel Assembly in Bulk Phases
12.3 Microgel Assembly at Interfaces
12.4 Influencing Factors of Microgel Assembly at Oil?Water Interfaces
12.5 Microgel Assembly for Stabilizing Biphasic Systems
12.6 Applications of Microgel Assembly at the Interface
12.7 Conclusions and Perspectives
 
13 Micro/Nano gels at fluid interfaces: single-particle properties and collective behavior
13.1 Introduction
13.2 Single-particle conformation
13.3 Microgel monolayers
13.4 Applications
13.5 Summary and perspective
 
14 Interfacial behavior of microgels revealed via direct visualization at fluid interfaces
14.1 Introduction
14.2 Formation of a microgel-based thin film via adsorption at the air?water interface
14.3 Deformation of microgels upon adsorption at the air?water interface
14.4 Adsorption behavior of microgels at the air?water interface during evaporation of a sessile droplet
14.5 Development of self-organization behavior of precisely designed micr

Prof. Takuma Kureha received his PhD (2018) from Shinshu University through a JSPS Research Fellowship (DC1, 2015-2018) on the synthesis of functional nanogels conducted under the supervision of Prof. Daisuke Suzuki. He then worked as a JSPS Postdoctoral Fellow (PD) at the Institute for Solid State Physics, University of Tokyo under the supervision of Prof. Mitsuhiro Shibayama, and since 2020, he has been leading an independent research life as an Assistant Professor at Hirosaki University. His current research interests include characterization of hydrogels and nanogels by scattering methods to control their functions.
 
Prof. Daisuke Suzuki obtained his PhD from Keio University (2007), before he went on to conduct postdoctoral studies at the University of Tokyo (2007-2009) as a JSPS research fellow (PD). He started his independent research career at Shinshu University in 2009 as a tenure-track Assistant Professor, where he was promoted to Associate Professor in 2013. He is a research representative of the Core Research for Evolutional Science and Technology (CREST) project. His current research is focused on the design, synthesis, and assembly of soft hydrogel and elastomer microspheres. His awards include the SPSJ Award for outstanding papers in Polymer Journal (sponsored by ZEON), the Award for Encouragement of Research in Polymer Science from the Society of Polymer Science (Japan), and the Ministry of Education, Culture, Sports, Science and Technology (MEXT) Young Scientists Prize (Japan).

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