Skip to main navigation
Skip to search
Skip to main content
Illinois Experts Home
LOGIN & Help
Home
Profiles
Research units
Research & Scholarship
Datasets
Honors
Press/Media
Activities
Search by expertise, name or affiliation
Mottness collapse and T-linear resistivity in cuprate superconductors
Philip Phillips
Physics
Chemistry
Research output
:
Contribution to journal
›
Review article
›
peer-review
Overview
Fingerprint
Fingerprint
Dive into the research topics of 'Mottness collapse and T-linear resistivity in cuprate superconductors'. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Keyphrases
Cuprate Superconductors
100%
Mottness
100%
T-linear Resistivity
100%
Spectral Weight
66%
Strange Metal
66%
Weight Transfer
66%
Fermi Gas
33%
Low Energy
33%
Metal Behavior
33%
Interaction System
33%
Resistivity
33%
Quantum Criticality
33%
Degrees of Freedom
33%
Fermionic
33%
High-Tc Cuprate Superconductor
33%
Pseudogap
33%
Hubbard Model
33%
One-parameter
33%
Energy Theory
33%
Extra Degree of Freedom
33%
Short-range Repulsion
33%
Parameter Scaling
33%
Low-band
33%
Robust Theory
33%
Engineering
Superconductor
100%
Degree of Freedom
100%
Length Scale
50%
Interacting System
50%
Critical Point
50%
Scaling Parameter
50%
Extra Degree
50%
Physics
Cuprates
100%
Degree of Freedom
100%
Physics
50%
High Temperature Superconductors
50%
Fermi Gas
50%
Critical Temperature
50%
Material Science
Superconducting Material
100%
Cuprate
100%
Electrical Resistivity
100%
High Temperature Superconductors
25%