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High Tc Superconductors

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Attempts to solve the problem. The inverted approach. QED3 ... Formalism. Start with the BdG Hamiltonian. FT transformation in order to avoid branch cuts. ... – PowerPoint PPT presentation

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Title: High Tc Superconductors


1
High Tc Superconductors QED3 theory of the
cuprates
  • Tami Pereg-Barnea
  • UBC
  • tami_at_physics.ubc.ca

QED3
2
outline
  • High Tc Known and unknown
  • Some experimental facts and phenomenology
  • Models
  • Attempts to solve the problem
  • The inverted approach
  • QED3 formulations and consequences

3
Facts
  • The parent compounds are AF insulators.
  • 2D layers of CuO2
  • Superconductivity is the condensation of Cupper
    pairs with a D-wave pairing potential.
  • The cuprates are superconductors of type II
  • The normal state is a non-Fermi liquid,
    strange metal.

4
YBCO microwave conductivity
BSCCOARPES
5
Neutron scattering (p,p) resonance in YBCO
Underdoped Bi2212
6
Phenomenology
  • The superconducting state is a D-wave BCS
    superconductors with a Fermi liquid of nodal
    quasiparticles.
  • The AF state is well described by a Mott-Hubbard
    model with large U repulsion.
  • The pseudogap is strange!
  • Gap in the excitation of D-wave symmetry but no
    superconductivity
  • Non Fermi liquid behaviour anomalous power laws
    in verious observables.

7
Phase diagram
AF
AF
AF
8
Theoretical approaches
  • Starting from the Hubbard model at ½ filling.
  • Slave bosons SU(2) gauge theories
  • Spin and charge separation
  • Stripes
  • Phenomenological
  • SO(5) theory
  • DDW competing order

9
The inverted approach
  • Use the phenomenology of d-SC as a starting
    point.
  • Destroy superconductivity without closing the
    gap and march backwards along the doping axis.
  • The superconductivity is lost due to
    quantum/thermal fluctuations in the phase of the
    order parameter.

10
Vortex Antivortex unbinding
Emery Kivelson Nature 374, 434 (1995) Franz
Millis PRB 58, 14572 (1998)
11
Phase fluctuations
  • Assume D0 D const.
  • Treat expif(r) as a quantum number sum over
    all paths.
  • Fluctuations in f are smooth (spin waves) or
    singular (vortices).
  • Perform the Franz Teanovic transformation - a
    singular gauge transformation.
  • The phase information is encoded in the dressed
    fermions and two new gauge fields.

12
Formalism
  • Start with the BdG Hamiltonian
  • FT transformation in order to avoid branch cuts.

13
The transformed Hamiltonian
  • The gauge field am couples minimally ?m ? am
  • The resulting partition function is averaged over
    all A, B configurations and the two gauge fields
    are coarse grained.

14
The physical picture
  • RG arguments show that vm is massive and
    therefore its interaction with the Toplogical
    fermions is irrelevant.
  • The am field is massive in the dSC phase
    (irrelevant at low E) and massless at the
    pseudogap.
  • The kinetic energy of am is Maxwell - like.

15
Quantum Electro Dynamics
  • Linearization of the theory around the nodes.
  • Construction of 2 4-component Dirac spinors.

16
Dressed QPs
Optimally doped BSCCO Above Tc T.Valla et al.
PRL (00)
QED3 Spectral function
17
Chiral Symmetry Breaking ? AF order
  • The theory of Quantum electro dynamics has an
    additional symmetry, that does not exist in the
    original theory.
  • The Lagrangian is invariant under the global
    transformation where G is a linear
    combination of

18
  • The symmetry is broken spontaneously through the
    interaction of the fermions and the gauge field.
  • The symmetry breaking (mass) terms that are added
    to the action, written in the original nodal QP
    operators represent
  • Subdominant dis SC order parameter
  • Subdominant dip SC order parameter
  • Charge density waves
  • Spin density waves

19
Antiferromagnetism
  • The spin density wave is described by
  • where ?, ? labels denote nodes.
  • The momentum transfer is Q, which spans two
    antipodal nodes.
  • At ½ filling, Q ? (?,?) commensurate
    Antiferromagnetism.

_
20
Summary
  • Inverted approach dSC ? PSG ? AF
  • View the pseudogap as a phase disordered
    superconductor.
  • Use a singular gauge transformation to encode the
    phase fluctuation in a gauge field and get QED3
    effective theory.
  • Chirally symmetric QED3 ? Pseudogap
  • Broken symmetry ? Antiferromagnetism
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