APS March Meeting 2010
Volume 55, Number 2
Monday–Friday, March 15–19, 2010;
Portland, Oregon
Session D36: Focus Session: Bulk Properties of Complex Oxides -- Cobaltites and Vanadates
2:30 PM–4:54 PM,
Monday, March 15, 2010
Room: E146
Sponsoring
Units:
DMP GMAG
Chair: John Mitchell, Argonne National Laboratory
Abstract ID: BAPS.2010.MAR.D36.1
Abstract: D36.00001 : Impact of Na ordering on the electronic properties of the Co planes in Na$_{x}$CoO$_{2}$
2:30 PM–3:06 PM
Preview Abstract
Abstract
Author:
Henri Alloul
(Lab. Phys. des Solides, CNRS -UMR 8502, Paris Sud University, 91405 Orsay (France))
In 2003 superconductivity at 4.5K has been discovered in
Na$_{0.35}$CoO$_{2}$,1.3H$_{2}$O, a hydrated cobaltate. These
layered
cobaltates Na$_{x}$CoO$_{2}$ have some analogies with the
cuprates,~as 2D
conductivity occurs in the CoO$_{2}$ planes, where the Co are
arranged on a
triangular lattice, and doping can be modified by changing the Na
content.
But, contrary to the case of most cuprates for which dopant
induced disorder
is quite influential, the doping achieved in cobaltate samples is
associated
with the insertion of well ordered 2D Na structures and even 3D
ordered
stacks of the Na/Co planes. We found that the correlations
between magnetic
properties and Na structural order are uniquely probed locally
through
NMR/NQR measurements on both $^{23}$Na and $^{59}$Co nuclei.
The Na ordering appears responsible for very distinct electronic
ground
state properties of the metallic CoO$_{2}$ planes, which do exhibit
ferromagnetic in plane correlations for $x>$ 0.62 up to the
highest Na
content (except for x=1 which is a band insulator). These metallic
ferromagnetic correlations do not yield any static magnetic order
down to
$T$=0$^{(1)}$ for $x<$0.75, beyond which an AF 3D order occurs
(in plane
ferromagnetic with AF 3D stacking$^{(2)})$. On the contrary for
$x<$2/3, in
plane AF correlations appear$^{(3)}$, though static 3D AF
ordering at low
$T$ is only achieved for $x$=1/2 $^{(4)}$.
For $x>$0.5, the nature of the ground state and the anomalous
magnetic
properties are found to be linked with a charge segregation which
localizes
an ordered array of non magnetic Co$^{3+}$ sites in a metallic Co
background
responsible for the magnetic properties$^{(5)}$. This is contrary
to many
expectations for which Na order was expected to pin local
magnetic moments
in a metallic and less magnetic bath.
NMR/ NQR experiments have allowed us recently to determine the
atomic
structure of the $x$=2/3 phase. We demonstrated that the
associated Co charge
order is somewhat peculiar as the nearly ferromagnetic metallic
state
results of hole delocalization on a simple kagome lattice of Co
sites$^{(6)}$. Further efforts to determine the actual
arrangement of the
non magnetic cobalt sites for different Na concentrations is
presently
undertaken and should give hints to link the ground state
properties with
the Co charge arrangements.
\\[4pt]
[1] H. Alloul, I. Mukhamedshin, G. Collin , N. Blanchard,
Europhysics Lett. \textbf{82}, 17002 (2008).\\[0pt]
[2] S. P. Bayrakci S. P. et al., Phys. Rev. B, \textbf{69} (R)
100410 (2004).\\[0pt]
[3] G. Lang, J. Bobroff, H. Alloul, G. Collin, N. Blanchard,
Phys. Rev. B \textbf{78}, 155116 (2008).\\[0pt]
[4] J. Bobroff, G. Lang, H. Alloul, N. Blanchard, G. Collin,
Phys. Rev. Letters \textbf{96}, 107201 (2006).\\[0pt]
[5] I.R. Mukhamedshin, H.Alloul, N. Blanchard, G. Collin, Phys.
Rev. Letters \textbf{94}, 247602 (2005).\\[0pt]
[6] H.Alloul, I.R. Mukhamedshin, T. A. Platova, A.V. Dooglav,
Europhysics Lett. \textbf{85}, 47006 (2009)
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.MAR.D36.1