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Conduction in polymers. Dynamic disorder transport
A. Nitzan
*
, M. A. Ratner
*
Corresponding author for this work
School of Chemistry
Tel Aviv University
Research output
:
Contribution to journal
›
Article
›
peer-review
138
Scopus citations
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Keyphrases
Dynamic Disorder
100%
Hopping Model
100%
Renewal Time
75%
Frequency Dependence
50%
Glass Transition Temperature
50%
Two-time Scale
50%
Residence Time
50%
Percolation Model
50%
Polymer Hosts
50%
Debye
25%
One-site
25%
Analytic Continuation
25%
Solid State
25%
Physical Systems
25%
Relaxation Time
25%
Glass Transition
25%
Materials Science
25%
Polymer Dynamics
25%
Renewing
25%
Extended Systems
25%
Multiple Time Scales
25%
Glass-forming Liquids
25%
Percolation Threshold
25%
Diffusion Model
25%
Microemulsion
25%
Bond Percolation
25%
Disordered Models
25%
Polymeric Materials
25%
Continuous Time Random Walk
25%
Polymer Electrolyte
25%
Polymer Media
25%
Ionic Transport
25%
Formal Proof
25%
Hopping Motion
25%
Ionic Diffusion
25%
Hopping Dynamics
25%
Dynamic Bonds
25%
Time Scale Systems
25%
Neat Polymers
25%
State Theory
25%
Dynamical Disorder
25%
Electrolyte Materials
25%
Polymer Viscosity
25%
Chemical Interpretation
25%
Engineering
Hopping Model
100%
Renewals
75%
Realization
25%
Continuous Time
25%
Fluid Viscosity
25%
Diffusive
25%
Extended System
25%
Percolation Threshold
25%
Physical System
25%
Diffusion Model
25%
Neat Polymer
25%
Relaxation Time
25%
Microemulsion
25%
Material Science
Percolation
100%
Glass Transition Temperature
66%
Glass Transition
33%
Polymer Dynamics
33%
Microemulsions
33%
Polymer
33%
Polymer Electrolyte
33%
Chemical Engineering
Microemulsion
100%