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Advanced Computer Simulation Approaches for Soft Matter Sciences II
Edited by Christian Holm and Kurt Kremer
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Online price: £153.90
RRP: £171.00
You save £17.10 (10% discount) Series: Advances in Polymer Science Category: States of Matter, Mathematical Physics, Organic Chemistry, General Material Science |
This series presents critical reviews of the present and future trends in polymer and biopolymer science including chemistry, physical chemistry, physics and materials science. It is addressed to all scientists at universities and in industry who wish to keep abreast of advances in the topics covered.
Impact Factor Ranking: Always number one in Polymer Science. More information as well as the electronic version of the whole content available at: www.springerlink.com
1 M. Müller, F. Schmidt. Incorporating Fluctuations and Dynamics in Self-Consistent Field Theories for Polymer Blends.- 2 A. Arnold, C. Holm: Efficient Methods to Compute Lang Range Interactions for Soft Matter Systems.- 3 P. Linse: Simulation of Charged Colloids in Solution.- 4 J.-J. Weis, D. Levesque: Simple Dipolar Fluids as Generic Models for Soft Matter.-
Publication Details:
Binding: Paperback, 250 pages
ISBN: 9783642065507
Format: 235mm x 155mm
BIC Code: PHF, PHU, PN, PNNP, TGMT
Imprint: Springer
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Books in Series
Advances in Polymer Science
- Advanced Computer Simulation Approaches for Soft Matter Sciences I
- Advanced Computer Simulation Approaches for Soft Matter Sciences I
- Advanced Computer Simulation Approaches for Soft Matter Sciences II
- Advanced Computer Simulation Approaches for Soft Matter Sciences II
- Advanced Computer Simulation Approaches for Soft Matter Sciences III
- Advanced Computer Simulation Approaches for Soft Matter Sciences III
- Advanced Rubber Composites
- Bioactive Surfaces
- Biomedical Applications of Polymeric Nanofibers
- Biopolymers - Lignin, Proteins, Bioactive Nanocomposites
- Block Copolymers I
- Block Copolymers I
- Block Copolymers II
- Block Copolymers II
- Branched Polymers II
- Chemical Design of Responsive Microgels
- Chitosan for Biomaterials I
- Chitosan for Biomaterials II
- Chromatography for Sustainable Polymeric Materials - Renewable, Degradable and Recyclable
- Chromatography for Sustainable Polymeric Materials - Renewable, Degradable and Recyclable
- Complex Macromolecular Systems I
- Complex Macromolecular Systems II
- Conformation-Dependent Design of Sequences in Copolymers I
- Conformation-Dependent Design of Sequences in Copolymers I
- Conformation-Dependent Design of Sequences in Copolymers II
- Crosslinking in Materials Science - Technical Applications
- Crosslinking in Materials Science - Technical Applications
- Degradable Aliphatic Polyesters
- Emissive Materials - Nanomaterials
- Emissive Materials - Nanomaterials
- Enzymatic Polymerisation
- Enzyme-Catalyzed Synthesis of Polymers
- Enzyme-Catalyzed Synthesis of Polymers
- Filler-Reinforced Elastomers / Scanning Force Microscopy
- Fuel Cells I
- Fuel Cells I
- Fuel Cells II
- Fuel Cells II
- Functional Materials and Biomaterials
- Functional Materials and Biomaterials
- High Solid Dispersions
- Hybrid Latex Particles - Preparation with (Mini)emulsion Polymerization
- Hydrogen Bonded Polymers
- Hydrogen Bonded Polymers
- Inclusion Polymers
- Inclusion Polymers
- Inorganic Polymeric Nanocomposites and Membranes
- Inorganic Polymeric Nanocomposites and Membranes
- Interfacial Processes and Molecular Aggregation of Surfactants
- Interfacial Processes and Molecular Aggregation of Surfactants
- Interphases and Mesophases in Polymer Crystallization I
- Interphases and Mesophases in Polymer Crystallization I
- Interphases and Mesophases in Polymer Crystallization II
- Interphases and Mesophases in Polymer Crystallization II
- Interphases and Mesophases in Polymer Crystallization III
- Intrinsic Molecular Mobility and Toughness of Polymers II
- Intrinsic Molecular Mobility and Toughness of Polymers II
- Liquid Chromatography / FTIR Microspectroscopy / Microwave Assisted Synthesis
- Mass Spectrometry of Polymers – New Techniques
- Metathesis Polymerization
- Metathesis Polymerization
- Microlithography/Molecular Imprinting
- Microlithography/Molecular Imprinting
- Modern Techniques for Nano- and Microreactors/-reactions
- Molecular Simulation/Fracture/Gel Theory
- Neodymium Based Ziegler Catalysts - Fundamental Chemistry
- Neodymium Based Ziegler Catalysts - Fundamental Chemistry
- Neutron Spin Echo in Polymer Systems
- Neutron Spin Echo in Polymer Systems
- New Developments in Polymer Analytics I
- New Frontiers in Polymer Synthesis
- New Frontiers in Polymer Synthesis
- Oligomers - Polymer Composites -Molecular Imprinting
- Oligomers - Polymer Composites -Molecular Imprinting
- Ordered Polymeric Nanostructures at Surfaces
- Ordered Polymeric Nanostructures at Surfaces
- Organic Electronics
- Peptide Hybrid Polymers
- Peptide Hybrid Polymers
- Phase Behavior of Polymer Blends
- Phase-Separated Interpenetrating Polymer Networks
- Phase-Separated Interpenetrating Polymer Networks
- Photoresponsive Polymers I
- Photoresponsive Polymers I
- Photoresponsive Polymers II
- Photoresponsive Polymers II
- Poly(arylene ethynylene)s - From Synthesis to Application
- Polyelectrolytes with Defined Molecular Architecture I
- Polyelectrolytes with Defined Molecular Architecture II
- Polyfluorenes
- Polyfluorenes
- Polymer Analysis/Polymer Theory
- Polymer Analysis/Polymer Theory
- Polymer Characterization - Rheology, Laser Interferometry, Electrooptics
- Polymer Libraries
- Polymer Materials - Block-Copolymers, Nanocomposites, Organic/Inorganic Hybrids, Polymethylenes
- Polymer Membranes/Biomembranes
- Polymer Particles
- Polymer Particles
- Polymer Synthesis
- Polymer Therapeutics I - Polymers as Drugs, Conjugates and Gene Delivery Systems
- Polymer Therapeutics I - Polymers as Drugs, Conjugates and Gene Delivery Systems
- Polymer Therapeutics II - Polymers as Drugs, Conjugates and Gene Delivery Sytems
- Polymer Therapeutics II - Polymers as Drugs, Conjugates and Gene Delivery Sytems
- Polymer Thermodynamics - Liquid Polymer-Containing Mixtures
- Polymeric and Inorganic Fibers
- Polymeric and Inorganic Fibers
- Polymers and Light
- Polymers for Photonics Applications I
- Polymers for Photonics Applications II - Nonlinear Optical, Photorefractive and Two-Photon Absorption Polymers
- Polymers for Regenerative Medicine
- Polymers for Regenerative Medicine
- Polymers in Confined Environments
- Polymers in Nanomedicine
- Polysaccharides I - Structure, Characterisation and Use
- Polysaccharides I - Structure, Characterisation and Use
- Polysaccharides II
- Polysaccharides II
- Radiation Effects on Polymers for Biological Use
- Self Organized Nanostructures of Amphiphilic Block Copolymers I
- Self Organized Nanostructures of Amphiphilic Block Copolymers II
- Self-Assembled Nanomaterials I - Nanofibers
- Self-Assembled Nanomaterials I - Nanofibers
- Self-Assembled Nanomaterials II - Nanotubes
- Self-Assembled Nanomaterials II - Nanotubes
- Shape-Memory Polymers
- Silicon Polymers
- Statistical, Gradient and Segmented Copolymers by Controlled/Living Radical Polymerizations
- Supramolecular Polymers/Polymeric Betains/Oligomers
- Supramolecular Polymers/Polymeric Betains/Oligomers
- Surface-Initiated Polymerization I
- Surface-Initiated Polymerization I
- Surface-Initiated Polymerization II
- Surface-Initiated Polymerization II
- Synthetic Biodegradable Polymers
- Wax Crystal Control - Nanocomposites - Stimuli-Responsive Polymers
- Wax Crystal Control - Nanocomposites - Stimuli-Responsive Polymers
