Quantum Phase Transitions
Week 11
21st March - 25th March, 2005
Bloggers: Andrey
Chubukov & Piers Coleman
This was the week of the APS March meeting,
but many participants preferred the quiet of Santa Barbara to the
crowded Conference Center at Los Angeles. The weather continued to be
touchy and on Tuesday, we had 2.5 ins of rain! By the end of the
week however, the weather had turned sunny again, and we're all hoping
this is how it will stay for the remainder of the program. Mike
Norman has left our ranks, to return to Argonne National Lab in
Chicago, with his digital camera, so for the moment, there will be no
more "action shots" of the black-board and presentations. Mike -
thanks for helping out with the blog for the past five weeks.
On Tuesday, we had an informal session on ruthenates and Ce-based
115 materials, with Andy Schofield and Andrey Chubukov leading a lively
discussion. The Thursday Founder's Room discussion focussed on
the "kink" observed by ARPES in the dispersion of electrons in the
normal state of cuprate superconductors. Is this kink due to phonons,
or some other mass renormalization process? To find the answer to
this question, read on!
Participants
Blackboard Seminar
Experimental
Seminar
Thursday Discussion
Participants
present.
Click on participant to read questions that they have posed.
Abrahams, Elihu
Chubukov, Andrey
Coleman, Piers
Efetov, Kostya
Eshrig, Mathias
Feldman, Dima
Geshkenbein, Vadim
Kroha, Johannes
Larkin, Anatoli
Monien, Hartmut
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Morr, Dirk
Pepin,
Catherine
Posazhennikova, Anna
Schofield, Andrew
Schmalian, Joerg
Si, Qimiao
Turlakov, Misha
Weng, Zheng-Yu
Yakovenko,Victor
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Monday Blackboard
Discussion. Not held this week.
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Discussion
Seminar,
12.30pm Tuesday, March 22nd.
At an SDW quantum critical point
the Fermi surface reconstructs leading to sharp corners of the Fermi
surface with radius of curvature  /vF.
The the usual weak-field magnetotransport requires that quasiparticles
do not precess around the corners between scattering events:  . This
can never be met at a field driven quantum critical point and leads to
new behaviour.
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Andy Schofield
began with a discussion of his current work
in collaboration with Joe Fenton at the University of Birmingham, UK
(unpublished). They point out that the collapse of an energy scale at a
QCP can have important consequences for transport. They showed that the
weak-field regime for magneto transport with an SDW gap of size is . This
means that
the order of limits  and  is
important. Andy
argued that at a field driven QCP, one should expect
discontinuities in the conductivity, and that at a non-field driven QCP
in a clean metal, the magnetoresistance would be linear in field. He
speculated that this effect might be seen in clean Cr1-xVx. |
| In the second presentation, Andrey Chubukov reviewed
recent experimental work by L. Taillefer and co-workers (cond-mat/0503342)on
thermal conductivity in CeCoIn5. This material becomes
superconducting at Tc =2.3K$, and there are experimental
reasons to believe that superconductivity is of dx2-y
symmetry. The issue they addressed is how the system properties evolve
upon adding non-magnetic impurities which in their case were
introduced by
substituting Ce by La. |
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This group measured the specific heat of Ce1-x Lax
CoIn5 and found that Tcis depressed, and that
furthermore, as x increases, a residual, normal component of 
develops, growing with doping.This is consistent with theory,
where
impurities in a $d-$wave superconductor produce a finite DOS near the
nodes, with a magnitude of DOS which scales with La doping,
x . |
The group also measured thermal conductivity. In the normal
state,  should scale inversely
with the Lanthanum concentration, x, by the
Wiedemann-Franz law, and this precise behavior was indeed observed. In
a superconducting state, the theory of Durst and Lee and others
predicts that
should be independent of x, for the normal state 1/x
dependence is
now balanced by the DOS which scales as x. Surprisingly, they
observed that still
follows a 1/x dependence. Taillefer et al conjectured that a
possible
explanation may be that a portion of electrons (from one of the two
Fermi surface sheets) does not participate in the pairing. Hopefully,
theorists will address this issue in near future. |
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Discussion:
4:30 pm Thursday, March 24th Founders Room.
The "kink" in the electron dispersion, after A.
Lanzara, P.
V. Bogdanov, X. J.
Zhou, S.
A. Kellar, D. L.
Feng, E. D. Lu,
T.
Yoshida, H.
Eisaki, A.
Fujimori, K.
Kishio, J.
-I. Shimoyama, T.
Noda, S.
Uchida, Z.
Hussain, Z.-X.
Shen, Nature 412, 510-514 (2001), cond-mat/0102227.
On Thursday, we all paid respect to our own media-driven
craziness, and
discussed in great detail the ``kink'' in the cuprates. Elihu Abrahams
presented a detailed overview of the experimental situation. He
formulated several questions for the experimentalists:
---
what is the
temperature, doping and angular dependence of the kink?
--- how strong is the isotope effect?
--- what is the role of bi-layers?
and for theorists:
--- phonons vs spin
fluctuations?
--- the role of strong
correlations?
--- why doesn't the
high energy dispersion extrapolate to kF?
--- a possible relation
between the kink and the pairing
mechanism?
Dirk Morr presented the ``phonon story'' (but was he really playing the
role of Devils advocate?), following recent work by
Tom Devereaux and co-workers. The ``phonon'' explanation of the
kink involves two phonon modes, the B1g mode at 35
meV, which is responsible for the kink near antinodal points, and the
breathing mode at 70 meV, which is responsible for the kink along the
nodal direction. The coupling
constant for the breathing mode is very small, and this
eliminates an S-shape dispersion, which one would generally
expect when a fermion is coupled to a mode. At the same time, the
observed velocity renormalization along nodal direction is believed to
be of order one, so some other, non-phonon mechanism must be
responsible for this.
Matthias Eschrig discussed recent neutron scattering results on the
effect of the replacement  on the
resonance peak. The data show that the position of the peak does not
change, but the resonance becomes broader.
Werner Hanke discussed his current work on the role of vertex
corrections for the coupling to bosons. He argued that, when Mott
physics is relevant, vertex corrections are large, and cannot be
neglected.
Finally, Andrey Chubukov presented a ``spin-fluctuation'' scenario for
the kink. He described recent work with Mike Norman on the angular,
temperature and doping dependence of the fermionic dispersion. He
argued that in the spin-fluctuation scenario, the normal state
dispersion has crossover ( called a ``soft kink'' by one of
participants) at a frequency where the system crosses over from a Fermi
liquid to a non-Fermi liquid regime.The crossover frequency is
smaller for antinodal fermions. Above the crossover, the real
part of the self-energy is nearly flat , and this gives
rise to a linear dispersion which
interpolates inside the Fermi surface. In the superconducting
state, the magnetic scenario predicts an s-shape dispersion for
antinodal fermions due to the coupling to the spin $(\pi,\pi)$
resonance, but no s- shape dispersion for nodal fermions which do not
couple to the resonance by symmetry reasons. Andrey argued that this
explanation is consistent with the data.
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