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Viscous flow in simple organic liquids
W. T. Laughlin,
D. R. Uhlmann
Research output
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Contribution to journal
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Article
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peer-review
429
Scopus citations
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Keyphrases
Bending Beam
50%
Coefficient of Thermal Expansion
50%
Corresponding States
100%
Cresol
100%
Crystalline State
50%
Falling Sphere
50%
Flow Behavior
50%
Flow Process
50%
Free Volume Model
50%
Free Volume Theory
50%
Glass State
50%
Glass Transition
50%
Glass Transition Temperature
50%
Heat Capacity
50%
High Temperature Region
50%
Liquid Viscosity
50%
Low-temperature Region
50%
Modified Free Volume Theory
50%
Molecular Dynamics Calculations
50%
Normalization Factor
50%
O-terphenyl
50%
Organic Liquids
100%
Salacinol
50%
State Parameter
100%
Viscosimeter
50%
Viscous Flow
100%
Engineering
Beam Bending
50%
Coefficient of Expansion
50%
Crystalline State
50%
Flow Behavior
50%
Fluid Viscosity
100%
Free Volume Theory
100%
Free-Volume Model
50%
Heat Capacity
50%
Liquid Viscosity
50%
Process Flow
50%
Temperature Region
100%
Temperature Relation
50%
Viscous Flow
100%
Chemistry
Corresponding State
66%
Cresol
66%
Free Volume
100%
Glass Transition
33%
Glass Transition Temperature
33%
Thermal Expansion Coefficient
33%
Viscous Flow
100%
Physics
Glass Transition Temperature
50%
Molecular Dynamics
50%
Organic Liquid
100%
Thermal Expansion
50%
Viscometer
50%
Viscous Flow
100%
Chemical Engineering
Specific Heat
100%
Viscous Flow
100%
Material Science
Free Volume
100%
Glass Transition
33%
Glass Transition Temperature
33%