Paper ID # |
Title |
Topic Area |
Contact Author
First Name
|
Contact Author
Last Name |
Contact Author
Organization |
| 34 |
Application of Kinetic Crack Growth Theory to Non-Degradable-Fiber Reinforced Viscoelastic Matrix Composites |
7. Time (Rate)-Dependent Composite Materials |
Jun Jun |
Koyanagi |
Japan Aerospace Exploration Agency Sagamihara, Kanagawa |
| 35 |
Analysis of Time-Dependent Deformation for CFRP Mirror Under Hot and Humid Environment |
7. Time (Rate)-Dependent Composite Materials |
Yoshihiko |
Arao |
Waseda University |
| 38 |
Equilibrium and Non-Equilibrium Molecular Dynamics Simulations of Flexible and Semiflexible Polymer Melts: Dynamic Properties |
16. Numerical Analysis |
Martin |
Steinhauser |
|
| 39 |
Study on the Micromechanics Modeling for
Predicting the Viscoelastic Behavior of
Poly(Ethylene)Terephtalates (PET) Reinforced by
Spherical Glass Beads |
3. Viscoelasticity Modeling |
Julie |
Diani |
CNRS Paris |
| 41 |
On the Large Deflections of Viscoelastic Beams |
4. Viscoplasticity Modeling |
Murilo Augusto |
Vaz |
Federal University of Rio de Janeiro |
| 42 |
Environmental Effects of Moist and Dry Air on Creep Behavior of 347 Stainless Steel |
1. Experimental Methods and Mechanics of Testing |
Karol |
Schrems |
US DOE National Energy Technology Laboratory-Albany |
| 43 |
Study of Enhancement Mechanism and Synergistic Effects of Polymer/Clay Nanocomposite |
4. Viscoplasticity Modeling |
Yaning |
Li |
University of Michigan Ann Arbor |
| 44 |
Coarse-Grained Molecular Dynamics Simulations of Self Healing Polymeric Networks |
9. Dynamic Rate-Dependent Behaviors |
Taner |
Dirama |
Universal Technology Corporation Dayton, Ohio |
| 45 |
Nanoindentation and the Dynamic Characterization of Viscoelastic Solids |
1. Experimental Methods and Mechanics of Testing |
Erik Gregory |
Herbert |
MTS Nano Instruments Innovation Center Oak Ridge |
| 49 |
Viscoelastic Rate-sensitive Plastic Constitutive Law for Fiber-Reinforced Composites |
7. Time (Rate)-Dependent Composite Materials |
Kwansoo |
Chung |
Seoul National University |
| 50 |
On the Pressure Dependence of Neat and Particle Filled Polypropylene Compounds |
2. Experimental Material Characterization |
Michael |
Jerabek |
Polymer Competence Center Leoben GmbH |
| 51 |
Poisson's Ratio Of Polypropylen in Relaxation, Creep and Constant Rate of Strain Tests |
2. Experimental Material Characterization |
Daniel Thomas |
Tscharnuter |
Polymer Competence Center Leoben GmbH |
| 52 |
Time-dependent and Moisture Mechanisms in the Fracture of Paper |
10. Time (Rate)-Dependent Damage and Failure |
H.W. |
Haslach |
University Of Maryland, College Park |
| 55 |
Rheological Probes of the Relaxation Dynamics Of Densely Packed Soft Objects |
2. Experimental Material Characterization |
Hans M. |
Wyss |
Harvard University |
| 56 |
Effect of Thermomechanical Properties on the Deformation During the Rubbery-Glassy Cooling Process of Polymers |
3. Viscoelasticity Modeling |
Jandro L |
Abot |
University of Cincinnati |
| 57 |
Temperature Dependent Bending and Buckling of Glass-Ionoplast Laminates |
7. Time (Rate)-Dependent Composite Materials |
Jan Lodewijk |
Belis |
Ghent University Ghent (Zwijnaarde) |
| 58 |
Stochastic Constitutive Model of Amorphous Polymers |
3. Viscoelasticity Modeling |
James |
Caruthers |
Purdue University West Lafayette |
| 59 |
Time-Dependent Micro-Damage Accumulation in Multi-Fiber Model Composites: Effects of Inter-Fiber Spacing and Viscoelastic Matrices |
7. Time (Rate)-Dependent Composite Materials |
Fumio |
Ogawa |
Waseda University, Tokyo |
| 61 |
Force Measurements in High Speed Cutting Experiments |
1. Experimental Methods and Mechanics of Testing |
Florian |
Lourot |
Laboratoire de Fiabilité Mécanique Metz |
| 62 |
Viscoelastic Stiffness and Damping of Discrete Lattice Cells with High-Energy-State Components |
3. Viscoelasticity Modeling |
Yun-Che |
Wang |
National Cheng Kung University, Tainan |
| 63 |
Indentation of a Rigid Indenter with Arbitrary Profile into a Power-Law Creep Solid |
4. Viscoplasticity Modeling |
Yanping |
Cao |
Karlsruhe Research Center Eggenstein-Leopoldshafen |
| 64 |
Time-Dependent Multiaxial Deviatoric and Dilational Behaviour of Elastomeric Materials |
3. Viscoelasticity Modeling |
Vincent Anthony |
Coveney |
UWE, Bristol |
| 65 |
Time Dependent Plastic Deformation Recovery in Freestanding Nanocrystalline Metal Films |
15. Polycrystalline, Single Crystal and Nanocrystalline Behaviors |
Taher |
Saif |
University of Illinois at Urbana-Champaign |
| 66 |
Mechanical Behaviors of Isocyanate-Crosslinked Vanadium Oxide Aerogels |
2. Experimental Material Characterization |
Hongbing |
Lu |
Oklahoma State University Stillwater |
| 67 |
Measurement of Young's Modulus of Human Tympanic Membrane at High Strain Rates Using a Miniature Split Hopkinson Tension Bar |
2. Experimental Material Characterization |
Hongbing |
Lu |
Oklahoma State University Stillwater |
| 68 |
Constitutive Modeling of Epoxy using the Mulliken-Boyce Model for Glassy Polymers |
2. Experimental Material Characterization |
Jason |
Foley |
Air Force Research Laboratory Eglin AFB |
| 69 |
Kinetics of Degradation of High Temperature PMR-15 Polymer Resin |
7. Time (Rate)-Dependent Composite Materials |
Gregory |
Schoeppner |
Wright-Patterson AFB |
| 70 |
Thermo-Viscoplastic Deformation of Metal Alloys |
4. Viscoplasticity Modeling |
Farid H. |
Abed |
Bradley University Peoria |
| 71 |
Generalized Viscoelastic Designer Functionality Graded Auxetic Materials Engineered/Tailored for Specific Task Performances |
3. Viscoelasticity Modeling |
Harry |
Hilton |
University of Illinois (UIUC) Urbana |
| 72 |
Accelerated Ageing Modeling for Glass-reinforced Concrete and Polymer Composites |
2. Experimental Material Characterization |
Jason |
Cain |
Virginia Polytechnic Institute and State University Blacksburg |
| 73 |
Development of a Viscoelastic Continuum Damage Model for Cyclic Loading |
10. Time (Rate)-Dependent Damage and Failure |
Rani Warsi |
Sullivan |
Mississippi State University |
| 74 |
A Viscoplastic Constitutive Model for Active Braze Alloys |
4. Viscoplasticity Modeling |
Michael |
Neilsen |
Sandia National Laboratories |
| 75 |
A Computational Framework for Analyzing the Dynamic Behavior and Failure of Polymeric Glasses |
9. Dynamic Rate-Dependent Behaviors |
Amine |
Benzerga |
Texas A&M University |
| 76 |
Durability of Dynamically Loaded Polymeric Products |
9. Dynamic Rate-Dependent Behaviors |
Barbara |
Zupancic |
University of Ljubljana, Center for Experimental Mechanics |
| 77 |
Dynamical Analysis of Climbing Ropes |
1. Experimental Methods and Mechanics of Testing |
Anatolij |
Nikonov |
University of Ljubljana, Center for Experimental Mechanics |
| 78 |
Deformation and Ductile Fracture of High Strength Low Alloyed Steels Under High Strain Rate Loading |
1. Experimental Methods and Mechanics of Testing |
Lothar W. |
Meyer |
Chemnitz University of Technology CHEMNITZ, Saxony |
| 79 |
Effect of Heat Treatment Conditions on the Dynamic Strength and Failure Behavior of Titanium Alloy Ti-6Al-4V |
2. Experimental Material Characterization |
Lothar W. |
Meyer |
Chemnitz University of Technology CHEMNITZ, Saxony |
| 80 |
Shear Strength and Shear Failure, Overview on Testing and Behavior |
1. Experimental Methods and Mechanics of Testing |
Lothar W. |
Meyer |
Chemnitz University of Technology CHEMNITZ, Saxony |
| 81 |
High Rate Material Behaviour at Hot Forming Conditions |
1. Experimental Methods and Mechanics of Testing |
Lothar W. |
Meyer |
Chemnitz University of Technology CHEMNITZ, Saxony |
| 82 |
Simulations of Closed-Cell Polymeric Foam in Compression |
2. Experimental Material Characterization |
Hongbing |
Lu |
Oklahoma State University Stillwater |
| 83 |
An Anisotropic Nonlinear Viscoelastic Model for Soft Fiber-Reinforced Composites |
3. Viscoelasticity Modeling |
Thao (Vicky) |
Nguyen |
John Hopkins University |
| 84 |
Viscoelastic Response of Ultrathin Polymer Films and Surfaces: Is There a Liquid Layer? |
2. Experimental Material Characterization |
Gregory |
McKenna |
Texas Tech University |
| 85 |
Instrument Compliance Effects in Measuring the Viscoelastic Response of Glass-forming Liquids and Polymers |
2. Experimental Material Characterization |
Gregory |
McKenna |
Texas Tech University |
| 88 |
Prediction of Long-term Creep Life for Unidirectional CFRP |
7. Time (Rate)-Dependent Composite Materials |
Masayuki |
Nakada |
Kanazawa Institute of Technology Hakusan, Ishikawa |
| 89 |
Prediction of Long-Term Fatigue Strength of Quasi-Isotropic CFRP Laminates with a Hole Under Compressive Loading |
7. Time (Rate)-Dependent Composite Materials |
Hongneng |
Cai |
Kanazawa Institute of Technology Hakusan, Ishikawa |
| 90 |
Polyurea: Characterization Modeling, and Dynamic Performance Evaluation |
TECHNICAL PLENARY |
Sia |
Nemat-Nasser |
UC San Diego |
| 100 |
Statistical Models for Modal Parameters in Civil Structure Continuous Monitoring |
10. Time (Rate)-Dependent Damage and Failure |
Rosario |
Ceravolo |
Politecnico di Torino |
| 102 |
Creep Properties of an A356 Composite Reinforced with SiC Particulates |
7. Time (Rate)-Dependent Composite Materials |
Mahdi |
Arhami |
Eastern Mediterranean University |
| 104 |
Mechanical Performance of Thermoplastic Polymers at High Strain Rates
|
9. Dynamic Rate-Dependent Behaviors |
Bernhard |
Moeginger |
FH Bonn-Rhein-Sieg University of Applied Sciences |
| 105 |
Time-Dependent-Surface Properties of a Piezoelectric Polymer
|
2. Experimental Material Characterization |
Hong |
Liang |
Texas A&M University |
| 107 |
A Novel Mathematical Tool for Characterizing Petroleum Fluid Rheology within Porous Media |
16. Numerical Analysis |
M. Enamul |
Hossain |
Dalhousie University |
| 108 |
A Novel Fluid Flow Model with Memory for Porous Media Application |
16. Numerical Analysis |
M. Enamul |
Hossain |
Dalhousie University |
| 110 |
Micromechanical and Compositional Design of Thermal Barrier Coatings for Modifying Time-dependent Behavior |
2. Experimental Material Characterization |
Klod |
Kokini |
Purdue University |
| 112 |
Effect of Crosslinking on Nanoindentation of Polyamides |
3. Viscoelasticity Modeling |
Suresh |
Ahuja |
Xerox Corporation |
| 113 |
Time Dependent Response of Ellipsoidal Suspensions to Homogeneous Shear |
9. Dynamic Rate-Dependent Behaviors |
Charles |
Petty |
Michigan State University |
| 114 |
Strain Rate and Pressure Dependence of Aluminum Under Dynamic Loading |
9. Dynamic Rate-Dependent Behaviors |
Tracy |
Vogler |
Sandia National Laboratories |
| 115 |
Use of Time-dependent Recovery Surfactants for Heat Transfer Control in Drag-reducing Applications |
5. Transport, Multiphase, and Biomaterial Systems |
Eric |
Matthys |
University of California, Santa Barbara |
| 117 |
Development of Early Age Shrinkage Stresses in Reinforced Concrete Bridge Decks |
3. Viscoelasticity Modeling |
Gergis |
William |
West Virginia University |
| 119 |
Time-Dependent Adhesion Between Sapphire Sphere and Polymeric Substrate |
2. Experimental Material Characterization |
Jae-Hyun |
Kim |
KIMM |
| 121 |
Dynamic Damage and Failure: Shear Bands and Voids |
10. Time (Rate)-Dependent Damage and Failure |
Thomas |
Wright |
US Army Research Laboratory |
| 122 |
Biphasic Poroviscoelastic Finite Element Indentation Simulation of Hydrogels |
16. Numerical Analysis |
Kaifeng |
Liu |
University of Notre Dame |
| 123 |
Change of type of Vorticity Transport and the Physics of Heat Transfer Enhancement in Non-Circular Tube Flow of Nonlinear Viscoelastic Fluids |
5. Transport, Multiphase, and Biomaterial Systems |
Dennis |
Siginer |
Wichita State University |
| 124 |
Experimental Characterization and Constitutive Modeling Polycarbonate Under Large Strains and Rapid Loads |
4. Viscoplasticity Modeling |
Mehrdad |
Negahban |
University of Nebraska-Lincoln |
| 125 |
Development of Biodegradable Material |
7. Time (Rate)-Dependent Composite Materials |
Rakesh |
Sagar |
IIT Delhi |
| 128 |
Modeling and Characterization of Time-Dependent Behavior of IM7/5250-4 Composite Subjected to Thermal Aging |
7. Time (Rate)-Dependent Composite Materials |
Samit |
Roy |
University of Alabama |
| 129 |
Viscoelastic Models Involving Fractional Derivatives of Different Orders |
3. Viscoelasticity Modeling |
Marina |
Shitikova |
Voronezh State University of Architecture and Civil Engineering |
| 130 |
Material Dependent Deformation Behavior in High-Velocity Metal Forming Processes |
4. Viscoplasticity Modeling |
Hakan |
Hallberg |
Division of Solid Mechanics, Lund University |
| 131 |
Spall of Hard Engineering Alloys: Approach by Meso-Scale |
10. Time (Rate)-Dependent Damage and Failure |
Janusz R. |
Klepaczko |
Metz University |
| 132 |
Interference Effect on Strain-Concentration Factor of Cylindrical Bars with Double Circumferential U-Notches Under Static Tension |
1. Experimental Methods and Mechanics of Testing |
Hitham |
Tlilan |
The Hashemite University |
| 133 |
WAVET, a Custom Device Able to Measure Viscoelastic Properties of Wood Under Water-Saturated Conditions Up to 140°C. (WAVET : Environmental Vibration Analyser for Wood) |
1. Experimental Methods and Mechanics of Testing |
Vincent |
Placet |
CNRS UMR 6174 FEMTO-ST Institute |
| 135 |
Time-dependent, Nanoscale Contact Plasticity |
2. Experimental Material Characterization |
William |
Gerberich |
University of Minnesota |
| 137 |
Dynamics of 2-D Composites of Elastic and Visco-Elastic Layers |
9. Dynamic Rate-Dependent Behaviors |
Michael |
El-Raheb |
|
| 139 |
Viscoplastic Constitutive Models for Numerical Analyses of Geotechnical Problems |
16. Numerical Analysis |
Tadatsugu |
Tanaka |
University of Tokyo |
| 140 |
Hold-Time Effects on Elevated-Temperature Low-Cycle-Fatigue Behavior of Superalloys |
10. Time (Rate)-Dependent Damage and Failure |
Sooyeol |
Lee |
University of Tennessee |
| 141 |
Some Outstanding Problems in the Mechanics of Rubbery Solids |
TECHNICAL PLENARY |
Alan |
Gent |
University of Akron |
| 142 |
Unsnarling the Skeins: An Adaptive Coarse-Graining Scheme for the Simulation of Elastomer Networks |
3. Viscoelasticity Modeling |
Misty |
Davies |
Stanford University |
| 143 |
Aging and Enthalpy Relaxation in Polymer Nanocomposites |
7. Time (Rate)-Dependent Composite Materials |
Catherine |
Brinson |
Northwestern University |
| 146 |
Molecular Relaxation Behavior of Fatty Acid Based Vinyl Ester Resins |
2. Experimental Material Characterization |
Steven |
Boyd |
Army Research Laboratory |
| 147 |
A Novel Class of Bio-Inspired Mechanoactive Materials |
5. Transport, Multiphase, and Biomaterial Systems |
Melissa Knothe |
Tate |
Case Western Reserve University |
| 148 |
Thermal Rates Effects to the Shape Change of Thermally Induced Shape Memory Polymers |
2. Experimental Material Characterization |
H. Jerry |
Qi |
University of Colorado |
| 149 |
Ultrasound Metamaterials for Super-resolution Imaging |
14. Micro/Nano-Scale Behaviors |
Nicholas |
Fang |
University of Illinois |
| 150 |
Modeling and Simulation of the Hot-Embossing Process on Amorphous Polymers |
4. Viscoplasticity Modeling |
Nicoli |
Ames |
Sandia National Laboratories |
| 152 |
The Frequency Dependence of the Deformation and Failure Behavior of Engineering Polymers |
2. Experimental Material Characterization |
Zoltan |
Major |
University of Leoben |
| 153 |
Loading Rate Dependence of the Deformation and Failure Behavior of Engineering Polymers used in Safety Relevant Automotive Applications |
9. Dynamic Rate-Dependent Behaviors |
Zoltan |
Major |
University of Leoben |
| 154 |
Characterization and Simulation of the Time Dependent Rolling Behavior of Polymer Rollers |
1. Experimental Methods and Mechanics of Testing |
Zoltan |
Major |
University of Leoben |
| 155 |
Dynamic Tensile Tests and Material Constitutive Equations at the Intermediate Strain Rate |
10. Time (Rate)-Dependent Damage and Failure |
Jiho |
Lim |
|
| 156 |
Aging and Structural Recovery in Plasticizing Environments |
5. Transport, Multiphase, and Biomaterial Systems |
Gregory |
McKenna |
Texas Tech University |
| 157 |
Mechanical Hole Burning Spectroscopy as a Means to Characterize Material Dynamic Heterogeneity |
2. Experimental Material Characterization |
Gregory |
McKenna |
Texas Tech University |
| 158 |
Temperature and Humidity Effects on Nonlinear Viscoelastic Viscoplastic Behavior of Natural Fiber Composites |
7. Time (Rate)-Dependent Composite Materials |
Janis |
Varna |
Lulea University of Technology |
| 159 |
Viscoplastic Constitutive Model for Permanent Deformation of Asphalt Concrete |
4. Viscoplasticity Modeling |
Habtamu |
Zelelew |
Washington State University |
| 160 |
Local Field Assessment Inside Multiscale Composite Architectures |
16. Numerical Analysis |
Robert |
Lipton |
Louisiana State Univ. |
| 161 |
Sinc Convolution Solution of Viscoelastic Problems |
7. Time (Rate)-Dependent Composite Materials |
Frank |
Stenger |
University of Utah |
| 162 |
Surface Resonant States in Acoustic and Elastic Metamaterials |
9. Dynamic Rate-Dependent Behaviors |
Lee |
Fok |
University of California, Berkeley |
| 163 |
Unifying Time-Dependent Behaviors in Cohesive Soils |
4. Viscoplasticity Modeling |
Thomas |
Sheahan |
Northeastern University |
| 164 |
Dynamic, Transient, Mode I Crack Propagation with a Nonlinear, Viscoelastic Cohesive Zone |
10. Time (Rate)-Dependent Damage and Failure |
Jay |
Walton |
Texas A&M University |
| 166 |
Modelling Strategies to Predict The Viscoelastic Behaviour of Amorphous Glassy Polymers |
3. Viscoelasticity Modeling |
Alberto |
D'Amore |
The Second University of Naples |
| 168 |
A Micromechanical Modeling Approach for Analyzing Thermo-viscoelastic Responses of Particle Reinforced Composites |
7. Time (Rate)-Dependent Composite Materials |
Anastasia |
Muliana |
Texas A&M University |
| 171 |
On the Macro to Micro Insight in Megastructure Structural Behavior in One Simulation Framework without Submodelling |
14. Micro/Nano-Scale Behaviors |
Dubravka |
Mijuca |
University of Belgrade |
| 172 |
A Study of Evaluation about Stress Intensity Factor of the Material for a Cylinder of Small Output Engine of Having a Crack, a Circle-hole or an Inclusion Under Tensile Load |
1. Experimental Methods and Mechanics of Testing |
Syuutei |
Sasaki |
Applied Dynamics |
| 174 |
Multistage Fatigue Model on Viscoelastic Materials at Elevated Temperatures |
10. Time (Rate)-Dependent Damage and Failure |
Yibin Anna |
Xue |
Mississippi State University |
| 177 |
Rhelogical Behaviour and Physical Properties of Controlled-Release Protein-Based Bioplastics |
5. Transport, Multiphase, and Biomaterial Systems |
Inmaculada Martinez |
Garcia |
University of Huelva |
| 178 |
Modelling the Large Strain Solid Phase Deformation Behaviour Of Polymer Nanoclay Composites |
7. Time (Rate)-Dependent Composite Materials |
John |
Sweeney |
University of Bradford |
| 179 |
Dynamic Inflation of Elastomeric Spherical Membranes Undergoing Chemorheological Changes in Microstructure
|
10. Time (Rate)-Dependent Damage and Failure |
Alan |
Wineman |
University of Michigan |
| 182 |
A Multiscale Model for Predicting Failure Due to Multiple Evolving Cracks in Heterogeneous Viscoelastic Solids |
3. Viscoelasticity Modeling |
David |
Allen |
University of Nebraska |
| 185 |
Rate Dependent Traction-Separation Laws for Polyurea Coatings on Steel |
10. Time (Rate)-Dependent Damage and Failure |
Kenneth M. |
Liechti |
University of Texas at Austin |
| 186 |
The Nonlinear Viscoelastic Behavior of Polurea Coating |
3. Viscoelasticity Modeling |
Kenneth M. |
Liechti |
University of Texas at Austin |
| 187 |
Modeling the Viscoelastic Properties of an Adhesive During Cure |
2. Experimental Material Characterization |
Jan |
de Vreugd |
Delft University of Technology |
| 188 |
Aerospace Materials - Quest for Innovation |
GOVERNMENT PLENARY |
Thomas P. |
Russell |
AFOSR/NA |
| 189 |
Dynamic Bulk Behavior of the Low Profile (LPA) Based Molding Compounds |
2. Experimental Material Characterization |
Manoj K . |
Saraswat |
Delft University of Technology |
| 190 |
Tensile Properties of Latex Paint Films: Time, Temperature and Moisture Content |
3. Viscoelasticity Modeling |
Maria |
Charalambides |
Imperial College London |
| 191 |
Microstructure-Sensitive Notch Root Analysis |
15. Polycrystalline, Single Crystal and Nanocrystalline Behaviors |
G. M. |
Owolabi |
Georgia Institute of Technology |
| 192 |
Time-Temperature Reduced Relaxation Properties
of an Elastomer and Viscoelastic Wave Propagation
|
3. Viscoelasticity Modeling |
Wolfgang G. |
Knauss |
California Institute of Technology |
| 193 |
Time-Dependency in Modeling Patellofemoral Joint Mechanics |
4. Viscoplasticity Modeling |
Jeff |
Bischoff |
Zimmer Inc. |
| 194 |
International Opportunities in Materials Research Through the Air Force Office of Scientific Research |
GOVERNMENT PLENARY |
K. C. |
Goretta |
Asian Office of Aerospace Research and Development (AOARD) |
| 195 |
On the Development and Parameter Identification of Schapery-Type Constitutive Theories |
3. Viscoelasticity Modeling |
Martin |
Levesque |
École Polytechnique Montréal |
| 196 |
Mechanisms of Tertiary Creep of Single Crystal Superalloy |
4. Viscoplasticity Modeling |
Alexander |
Staroselsky |
Pratt and Whitney |
| 197 |
Boundary Conditions in a Reacting Elastic Solid-Fluid Mixture |
5. Transport, Multiphase, and Biomaterial Systems |
Richard |
Hall |
Air Force Reserach Laboratories |
| 199 |
Modeling and Characterization of Viscoelastic Polymer Composites Containing Damage |
7. Time (Rate)-Dependent Composite Materials |
Ramesh |
Talreja |
Texas A&M University |
| 200 |
Creep Properties of Glassy Polymers during Nonisothermal Physical Aging: Experiments and Theory |
3. Viscoelasticity Modeling |
Yunlong |
Guo |
University of Louisville |
| 201 |
A Thermoviscoelastic Model for Amorphous Shape Memory Polymers: Incorporating Structural and Stress Relaxation |
3. Viscoelasticity Modeling |
Thao (Vicky) |
Nguyen |
Johns Hopkins University |
| 202 |
Time Dependence of Excess Stress Caused by Hydrogen Absorption in Ball-Milled Magnesium
|
2. Experimental Material Characterization |
George |
Roy |
CANMET-MTL |
| 203 |
A Constitutive Theory for the Mechanical Response of Amorphous Metals at High Temperatures Spanning the Glass Transition Temperature: Application to Microscale Thermoplastic Forming |
3. Viscoelasticity Modeling |
Lallit |
Anand |
Massachusetts Institute of Technology |
| 204 |
TBD |
TBD |
Igor |
Emri |
University of Ljubljana |