Engineering & Materials Science
Polymer melts
100%
Polystyrenes
71%
Platelets
54%
Viscosity
43%
Dilution
41%
Rheology
39%
Molar mass
38%
Relaxation
36%
Brittle fracture
33%
Polymers
33%
Shear flow
33%
Constitutive equations
28%
Composite materials
20%
Macromolecules
17%
Biopolymers
16%
Shear viscosity
16%
Styrene
14%
Viscoelasticity
13%
Fillers
13%
Strain energy
13%
High density polyethylenes
12%
Nanocomposites
12%
Stretching
12%
Low density polyethylenes
11%
Intercalation
11%
Polymer solutions
10%
Covalent bonds
10%
Polydispersity
9%
Strain hardening
9%
Liquid crystal polymers
8%
Characterization (materials science)
8%
Pressure effects
7%
Shear stress
7%
Stress relaxation
7%
Liquids
7%
Relaxation time
7%
Crystalline materials
6%
Stars
6%
Graphite
5%
Crack initiation
5%
Glass transition
5%
Casting
5%
Strain rate
5%
Superconducting transition temperature
5%
Hot Temperature
5%
Chemical Compounds
Flow
44%
Brittle Fracture
44%
Dilution
40%
Shear
37%
Rheology
36%
Pressure
28%
Molar Mass
25%
Shear Stress
19%
X-Ray Weissenberg
18%
Composite Material
17%
Strain Energy
17%
Styrene
15%
Macromolecule
14%
Strain Hardening
14%
Stress Relaxation
12%
Filler
12%
Biopolymer
11%
Crack Initiation
10%
Polydispersity
9%
Time
9%
Shear Rheology
9%
Diethyl Phthalate
8%
Filament
8%
Nanocomposite
7%
Tacticity
7%
Glass Transition Temperature
7%
Strain
7%
Covalent Bond
7%
Solvent
6%
Intercalation Compound
6%
Simulation
5%
Methyl Methacrylate
5%
Casting
5%
Polymer Chain
5%
Physics & Astronomy
polymers
57%
polystyrene
50%
viscosity
43%
stress functions
34%
rheology
32%
shear flow
26%
dilution
25%
polyethylenes
18%
constitutive equations
18%
scaling
17%
shear
16%
predictions
15%
tubes
14%
macromolecules
12%
styrenes
11%
friction reduction
9%
characterization
8%
degradation
7%
filaments
6%
stress relaxation
6%
pressure effects
6%
platelets
6%
viscoelasticity
5%
cleavage
5%
covalent bonds
5%
rheometers
5%
nanocomposites
5%
graphite
5%
strands
5%
crack initiation
5%