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BL
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| Record Number
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841385
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| Main Entry
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Lakes, Roderic S.
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| Title & Author
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Viscoelastic Solids (1998).
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| Edition Statement
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First edition.
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| Publication Statement
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Boca Raton, FL :: CRC Press,, 2017.
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| Series Statement
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CRC Press Revivals
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| Page. NO
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1 online resource :: text file, PDF
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| ISBN
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1315121360
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: 1351355643
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: 1351355651
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: 9781315121369
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: 9781351355643
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: 9781351355650
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1138104930
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9781138104938
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9781138562899
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| Contents
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Â2.4 Relation between creep and relaxationÂ2.5 Stress vs. strain for constant strain rate; Â2.6 Particular creep and relaxation functions; Â2.7 Effect of temperature; Â2.8 Three-dimensional linear constitutive equation; Â2.9 Aging materials; Â2.10 Dielectric and other forms of relaxation; Â2.11 Adaptive and ""smart"" materials; Â2.12 Effect of nonlinearity; Â2.13 Summary; Chapter 3 Dynamic behavior; Â3.1 Introduction and rationale; Â3.2 The linear dynamic response functions; Â3.3 Kramers-Kronig relations; Â3.4 Energy storage and dissipation; Â3.5 Resonance of structural members.
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Â3.6 Decay of resonant vibrationÂ3.7 Wave propagation and attenuation; Â3.8 Measures of damping; Â3.9 Nonlinear materials; Â3.10 Summary; Chapter 4 Conceptual structure of linear viscoelasticity; Â4.1 Introduction; Â4.2 Spectra in linear viscoelasticity; Â4.3 Approximate interrelations among viscoelastic functions; Â4.4 Conceptual organization of viscoelastic functions; Â4.5 Summary; Chapter 5 Viscoelastic stress and deformation analysis; Â5.1 Introduction; Â5.2 Three-dimensional constitutive equation; Â5.3 Pure bending by direct construction; Â5.4 Correspondence principle.
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Â5.5 Pure bending reconsideredÂ5.6 Further examples with the correspondence principle; Â5.7 Dynamic problems; Â5.8 Noncorrespondence problems; Â5.9 Bending in nonlinear viscoelasticity; Â5.10 Dynamic response of nonlinear materials; Â5.11 Summary; Chapter 6 Experimental methods; Â6.1 Introduction: general requirements; Â6.2 Creep; Â6.3 Displacement and strain measurement; Â6.4 Force measurement; Â6.5 Load application; Â6.6 Environmental control; Â6.7 Subresonant dynamic methods; Â6.8 Resonance methods; Â6.9 The problem of achieving a wide range of time or frequency.
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Â6.10 Test instruments for viscoelasticityÂ6.11 Wave methods; Â6.12 Summary; Chapter 7 Viscoelastic properties of materials; Â7.1 Introduction; Â7.2 Overview: some common materials; Â7.3 Polymers; Â7.4 Metals; Â7.5 Rock and ceramics; Â7.6 Concrete; Â7.7 Asphalt; Â7.8 Ice; Â7.9 Piezoelectric materials; Â7.10 Biological materials; Â7.11 Porous materials; Â7.12 Composite materials; Â7.13 Inorganic amorphous materials; Â7.14 Common aspects; Â7.15 Summary; Chapter 8 Causal mechanisms; Â8.1 Introduction; Â8.2 Survey of viscoelastic mechanisms; Â8.3 Thermoelastic relaxation.
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Cover; Half Title; Title Page; Copyright Page; Contents; Chapter 1 Introduction: phenomena; Â1.1 Viscoelastic phenomena; Â1.2 Motivations for studying viscoelasticity; Â1.3 Transient properties: creep and relaxation; Â1.4 Dynamic response to sinusoidal load; Â1.5 Demonstration of viscoelastic behavior; Â1.6 Other works on viscoelasticity; Â1.7 Historical aspects; Â1.8 Summary; Chapter 2 Constitutive relations; Â2.1 Introduction; Â2.2 Prediction of the response of linearly viscoelastic materials; Â2.3 Restrictions on the viscoelastic functions; fading memory.
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| Abstract
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"Viscoelastic Solids covers the mathematical theory of viscoelasticity and physical insights, causal mechanisms, and practical applications. The book:presents a development of the theory, addressing both transient and dynamic aspects as well as emphasizing linear viscoelasticitysynthesizes the structure of the theory with the aim of developing physical insightillustrates the methods for the solution of stress analysis problems in viscoelastic objectsexplores experimental methods for the characterization of viscoelastic materialsdescribes the phenomenology of viscoelasticity in a variety of materials, including polymers, metals, high damping alloys, rock, piezoelectric materials, cellular solids, dense composite materials, and biological materialsanalyzes high damping and extremely low dampingprovides the theory of viscoelastic composite materials, including examples of various types of structure and the relationships between structure and mechanical propertiescontains examples on the use of viscoelastic materials in preventing and alleviating human sufferingViscoelastic Solids also demonstrates the use of viscoelasticity for diverse applications, such as earplugs, gaskets, computer disks, satellite stability, medical diagnosis, injury prevention, vibration abatement, tire performance, sports, spacecraft explosions, and music."--Provided by publisher.
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| Subject
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Viscoelastic materials.
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Viscoelasticity.
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TECHNOLOGY ENGINEERING-- Engineering (General)
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TECHNOLOGY ENGINEERING-- Reference.
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| Subject
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Viscoelastic materials.
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| Subject
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Viscoelasticity.
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| Dewey Classification
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620.1/1232
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| LC Classification
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TA418.2
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