Glassy Behavior of Electrons Near MetalInsulator Transitions

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Glassy Behavior of Electrons Near MetalInsulator Transitions

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Title: Glassy Behavior of Electrons Near MetalInsulator Transitions

1
Glassy Behavior of Electrons Near Metal-Insulator
Transitions (Is Mayonnaise a Metal or an
Insulator?)
Vladimir Dobrosavljevic Department of Physics
and National High Magnetic Field
Laboratory Florida State University
Collaborators Darko Tanaskovic (FSU) Andrei
Pastor (FSU) Sergey Pankov (Paris) Denis
Dalidovich (FSU) Marcelo Rozenberg
(Paris) Liliana Arachea (Trieste)
Funding NHMFL/FSU Alfred P. Sloan Foundation NSF
grant DMR-9974311
2
Contents

Glassiness a fundamental feature of MIT-s
What is known Coulomb gap, glassiness, no
screening?
EDMFT formulation for electron glasses
Classical model for electron glass
self-organized criticality
Long-range Coulomb interactions correlated
plasma vs. glass
Quantum melting of electron glass Anderson vs.
Mott localization

3
Evidence of Glassy Behavior near MIT-s noise
spectroscopy in MOSFETs (Dragana Popovic, FSU
PRL, 2002)
4
What is known about the Coulomb glass?
Coulomb Gap

Open questions (unknown unknowns)
Why is the bound saturated?
Why universal prefactor and exponent?
Relation to possible glassy freezing
ES assumed no screening. Why?
Role of quantum fluctuations, MIT?

Efros-Shklovskii theory r(e)
Cd(e-eF)d-1 (Bound !!) NOTE in ALL dimensions!!!
5
Glassy behavior of disordered electrons?
6
EDMFT approach controlled theory in large d A.
A. Pastor and V. Dobrosavljevic, PRL 83, 4642
(1999)
Physical content environment (cavity)
treated in a Gaussian approximation. (quasiparti
clesplasmons)
7
Results short-range repulsion

Uniform ordering (Wigner crystal)
at small disorder
Glassy phase (RSB) at strong disorder
TG 1/W at large disorder (Why?)
( AT line for SK model TG exp-W/V )

cool
Nothing interesting at T gt TG
GAP!!! at T 0
8
(No Transcript)
9
Exotic Features of the Electron Glass Phase
10
Long Range Coulomb Interactions (S. Pankov, V.
Dobrosavljevic 2003, unpublished)
d5 cubic lattice

Coulomb interactions are
strongly frustrating
Ordering temperature only
few percent of Coulomb energy U!!!
Strongly correlated Coulomb liquid
survives down to T ltlt Ue2/a
Small disorder (WltltU) destroys the
Wigner crystal
Disorder increases TG(W) at small W.

T/U
Disorder W/U
NOTE consistent with large critical rsU/EF (100
for clean d3 40 for clean d2 Ceperley
QMC) (10 for disordered d2 ChuiTanatar, 1995)
11
No Disorder Coulomb Plasma Correlation Gap
This gap is nonuniversal and similar in all
dimensions
MC simulations A. Efros, PRL 1992
12
Approaching the Coulomb Glass Pseudogap Phase
Simulation (T. Vojta, 1995)
At stronger disorder, the plasma dip disappears!
13
What about the Efros-Shklovskii gap?
Efros-Sklovskii theory r(e)
Cd(e-eF)d-1 Gap EG W-1/(d-1)
EG

Our analytical results give TG W-1/(d-1) (at W
large)
This suggests that the universal Coulomb gap
is a feature of the glassy phase.
Consistent with vanishing ZFC compressibility
at T0 in the glass phase, thus no screening

14
Quantum Melting of the Electron Glass
Glassy behavior deep in the insulator
(EfrosShklovskii, Pollak) Question when does
the glass melt?
Mobile electrons quantum
fluctuations MELT glass at T0
E-DMFT replica symmetry breaking (Parisi-like
scheme)
Diverges at Anderson-like transition Vanishes at
Mott transition
15
Global Phase Diagram DMFT picture of the
2D-MIT Dobrosavljevic, Tanaskovic, Pastor PRL
90, 016402 (2003)