Advances in asphalt materials: road and pavement construction (Record no. 3531)
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| fixed length control field | 09804nam a2200277Ia 4500 |
| 005 - DATE AND TIME OF LATEST TRANSACTION | |
| control field | 20250714113631.0 |
| 008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION | |
| fixed length control field | 241121s9999 xx 000 0 und d |
| 020 ## - INTERNATIONAL STANDARD BOOK NUMBER | |
| ISBN | 9780081002698 |
| 041 ## - LANGUAGE CODE | |
| Language code of text/sound track or separate title | eng |
| 082 ## - DEWEY DECIMAL CLASSIFICATION NUMBER | |
| Classification number | 625.85 HUA/A |
| 100 ## - MAIN ENTRY--AUTHOR NAME | |
| Personal name | Huang, Shin-Che (Editor) |
| 100 ## - MAIN ENTRY--AUTHOR NAME | |
| Personal name | Benedetto, Hervé Di (Editor) |
| 245 #0 - TITLE STATEMENT | |
| Title | Advances in asphalt materials: road and pavement construction |
| 260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) | |
| Name of publisher | Woodhead Publishing |
| Place of publication | Cambridge |
| Year of publication | c2015 |
| 300 ## - PHYSICAL DESCRIPTION | |
| Number of Pages | xxii, 470p.: ill.; 23cm. |
| 490 ## - SERIES STATEMENT | |
| Series statement | Woodhead Publishing Series in Civil and Structural Engineering: Number 56 |
| 500 ## - GENERAL NOTE | |
| General note | Table of contents<br/> • List of contributors<br/> • Woodhead Publishing Series in Civil and Structural Engineering<br/> • Preface<br/> • Introduction<br/> • 1: A perspective of bituminous binder specifications<br/> ◦ Abstract<br/> ◦ Acknowledgments<br/> ◦ 1.1 Scope and terminology<br/> ◦ 1.2 Introduction<br/> ◦ 1.3 What is a specification?<br/> ◦ 1.4 Regulatory frameworks<br/> ◦ 1.5 Test methods for use in binder specifications<br/> ◦ 1.6 Precision of test methods<br/> ◦ 1.7 Future specifications: fundamental or empirical binder testing?<br/> ◦ 1.8 Summary<br/> • Part One: Characterization and analysis of asphalt materials<br/> ◦ 2: Analytical separation methods in asphalt research<br/> ▪ Abstract<br/> ▪ Acknowledgments<br/> ▪ 2.1 Introduction<br/> ▪ 2.2 Separations of asphalts based on solvent precipitation and extraction<br/> ▪ 2.3 Separation methods based on adsorption chromatography<br/> ▪ 2.4 Methods for separation of asphalts into chemically distinct fractions by affinity chromatography<br/> ▪ 2.5 Size-exclusion chromatography separation of asphalts<br/> ▪ 2.6 Summary<br/> ▪ Disclaimer<br/> ◦ 3: Tridimensional linear viscoelastic behavior of bituminous materials<br/> ▪ Abstract<br/> ▪ 3.1 Introduction<br/> ▪ 3.2 Complex modulus and complex Poisson’s ratio tests<br/> ▪ 3.3 Example of 3D linear viscoelastic (LVE) experimental results on bituminous mixtures<br/> ▪ 3.4 3D LVE modeling: two springs, two parabolic elements, one dashpot (2S2P1D) model<br/> ▪ 3.5 Determining 3D LVE bituminous mixture properties from LVE binder properties<br/> ▪ 3.6 Determination of 3D LVE properties with acoustic wave propagation<br/> ▪ 3.7 Anisotropy<br/> ▪ 3.8 Future developments<br/> ◦ 4: Characterization of asphalt materials by scanning probe microscopy<br/> ▪ Abstract<br/> ▪ 4.1 Introduction<br/> ▪ 4.2 Sample preparation methods<br/> ▪ 4.3 Atomic force microscopy (AFM) analysis of surface structuring in asphalt thin films<br/> ▪ 4.4 Force–displacement AFM<br/> ▪ 4.5 Future trends<br/> • Part Two: Damage mechanisms<br/> ◦ 5: Cracking mechanisms in asphalt mixtures<br/> ▪ Abstract<br/> ▪ 5.1 Introduction<br/> ▪ 5.2 Key observations on cracking<br/> ▪ 5.3 Implementation of the critical condition approach using hot mix asphalt-fracture mechanics (HMA-FM)<br/> ▪ 5.4 Top-down cracking (TDC) performance model based on the critical condition approach<br/> ▪ 5.5 Summary and conclusions<br/> ▪ 5.6 Future research<br/> ◦ 6: Deformation mechanisms of bituminous materials<br/> ▪ Abstract<br/> ▪ 6.1 Introduction<br/> ▪ 6.2 High-temperature deformation<br/> ▪ 6.3 Ambient temperature deformation<br/> ▪ 6.4 Low-temperature deformation<br/> ▪ 6.5 Deformation-mechanism maps<br/> ▪ 6.6 Conclusions<br/> ◦ 7: Damage healing in asphalt pavements: theory, mechanisms, measurement, and modeling<br/> ▪ Abstract<br/> ▪ 7.1 Introduction<br/> ▪ 7.2 Evidence of healing in asphalt materials and in asphalt pavements<br/> ▪ 7.3 Hypothesized mechanism(s) of healing in asphalt materials<br/> ▪ 7.4 Healing in asphalt binders<br/> ▪ 7.5 Measuring healing in asphalt mixtures<br/> ▪ 7.6 Microdamage healing: impact of rest period and thermodynamic considerations<br/> ▪ 7.7 Future directions<br/> ◦ 8: The fatigue cracking of asphalt mixtures in tension and compression<br/> ▪ Abstract<br/> ▪ 8.1 Introduction<br/> ▪ 8.2 Isotropic viscoelastic properties of asphalt mixtures in tension<br/> ▪ 8.3 Anisotropic viscoelastic properties of asphalt mixtures in compression<br/> ▪ 8.4 Permanent deformation of asphalt mixtures in compression<br/> ▪ 8.5 Fatigue, endurance limit, and healing of asphalt mixtures<br/> ▪ 8.6 Fracture of asphalt mixtures in compression<br/> ▪ 8.7 Summary and conclusions<br/> ▪ 8.8 Future trends<br/> ◦ 9: Multiscale modeling approach for asphalt concrete and its implications on oxidative aging<br/> ▪ Abstract<br/> ▪ 9.1 Introduction<br/> ▪ 9.2 A multiscale perspective of asphalt concrete behavior<br/> ▪ 9.3 Oxidation at the molecular level<br/> ▪ 9.4 Effects of oxidation on asphalt materials<br/> ▪ 9.5 Linking asphalt binder and asphalt mixture oxidation impacts<br/> ▪ 9.6 Sequential multiscale approach for identifying oxidation impacts<br/> ▪ 9.7 Summary<br/> ▪ 9.8 Future trends<br/> ▪ 9.9 Sources of further information<br/> ◦ 10: Moisture damage in asphaltic mixtures<br/> ▪ Abstract<br/> ▪ Acknowledgments<br/> ▪ 10.1 Introduction<br/> ▪ 10.2 Moisture damage in asphalt mixtures<br/> ▪ 10.3 Constitutive modeling of moisture damage<br/> ▪ 10.4 Experimental characterization and mixture design of asphalt mixtures for moisture damage<br/> ▪ 10.5 Outlook for the future<br/> • Part Three: Alternative asphalt materials<br/> ◦ 11: Advances in the development of alternative binders from biomass for the production of biosourced road binders<br/> ▪ Abstract<br/> ▪ 11.1 Introduction<br/> ▪ 11.2 Alternative binders developed for full replacement<br/> ▪ 11.3 Binder developed for partial replacement<br/> ▪ 11.4 Vegetable fluxes and surfactants<br/> ▪ 11.5 General remarks about alternative binder development<br/> ▪ 11.6 Conclusions<br/> ◦ 12: Blending of virgin bitumen and RA binder in mixtures with high amounts of RA<br/> ▪ Abstract<br/> ▪ 12.1 Introduction<br/> ▪ 12.2 Research approach<br/> ▪ 12.3 Mixtures<br/> ▪ 12.4 Materials and processes<br/> ▪ 12.5 Stage extraction<br/> ▪ 12.6 Materials<br/> ▪ 12.7 Results and analysis<br/> ▪ 12.8 Conclusions<br/> ▪ 12.9 Future trends<br/> ◦ 13: Paving with asphalt emulsions<br/> ▪ Abstract<br/> ▪ 13.1 Introduction<br/> ▪ 13.2 Overview of emulsifier chemistry and emulsion recipes<br/> ▪ 13.3 Surface tension and surfactants (emulsifiers)<br/> ▪ 13.4 The emulsification process and emulsion properties<br/> ▪ 13.5 Fundamental aspects of dispersion stability of asphalt emulsions<br/> ▪ 13.6 Setting mechanism of emulsions<br/> ▪ 13.7 Characterization of emulsion residues<br/> ◦ 14: A new approach for aggregate grading optimization for mixtures<br/> ▪ Abstract<br/> ▪ Acknowledgments<br/> ▪ 14.1 Introduction<br/> ▪ 14.2 Theoretical background on aggregate packing<br/> ▪ 14.3 Proposed method of aggregate packing optimization<br/> ▪ 14.4 Examples of aggregate packing optimization<br/> ▪ 14.5 Mechanical performance and related discussion<br/> ▪ 14.6 Economic and environmental outlook<br/> ▪ 14.7 In situ validation of the GB5® mix design: development and large-scale roadwork of 2010–2014<br/> ▪ 14.8 Future trends<br/> ▪ 14.9 Conclusions<br/> • Index<br/> |
| 520 ## - SUMMARY, ETC. | |
| Summary, etc | The urgent need for infrastructure rehabilitation and maintenance has led to a rise in the levels of research into bituminous materials. Breakthroughs in sustainable and environmentally friendly bituminous materials are certain to have a significant impact on national economies and energy sustainability. This book will provide a comprehensive review on recent advances in research and technological developments in bituminous materials.<br/><br/>Opening with an introductory chapter on asphalt materials and a section on the perspective of bituminous binder specifications, Part One covers the physiochemical characterisation and analysis of asphalt materials. Part Two reviews the range of distress (damage) mechanisms in asphalt materials, with chapters covering cracking, deformation, fatigue cracking and healing of asphalt mixtures, as well as moisture damage and the multiscale oxidative aging modelling approach for asphalt concrete. The final section of this book investigates alternative asphalt materials. Chapters within this section review such aspects as alternative binders for asphalt pavements such as bio binders and RAP, paving with asphalt emulsions and aggregate grading optimization.<br/><br/><br/> |
| 650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM | |
| Topical Term | Engineering and technology |
| 650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM | |
| Topical Term | Railroads |
| 650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM | |
| Topical Term | Artificial road surface |
| 650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM | |
| Topical Term | Bituminous material |
| 650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM | |
| Topical Term | Pavement construction |
| 856 ## - ELECTRONIC LOCATION AND ACCESS | |
| Uniform Resource Identifier | https://doi.org/10.1016/C2014-0-02666-4 |
| 942 ## - ADDED ENTRY ELEMENTS (KOHA) | |
| Koha item type | Book |
No items available.