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Type of Document Dissertation Author Smith, Robert Steven URN etd-11202010-003915 Title Nuclear Magnetic Resonance Studies of Phase Separation in Two Systems: (La,Sr)CoO(3) and (La,Sr)CuO(4) Degree Doctor of Philosophy Department Physics, Department of Advisory Committee
Advisor Name Title Gregory Boebinger Committee Chair Arneil Reyes Committee Member James Brooks Committee Member Samuel Tabor Committee Member Vladimir Dobrosavljevic Committee Member Naresh Dalal University Representative Keywords
- Nuclear magnetic resonance
- superconductivity
- magnetism
Date of Defense 2010-10-26 Availability unrestricted Abstract Nuclear magnetic resonance measurements are reported for two systems: (La,Sr)CoO(3)and (La,Sr)CuO(4). The local nature of NMR finds local order at temperatures well
above the bulk phase transitions of these compounds. This demonstrates the important
role of fluctuations in strongly correlated systems.
(La,Sr)CoO(3): Nanoscale inhomogeneity in (La,Sr)CoO(3) has been investigated
in single crystal samples for 0.05≤x≤0.30 using (139)La and (59)Co NMR to probe
local magnetization. Ferromagnetism is only exhibited above the metal-to-insulator
(MIT) critical concentration, x(C). However, over the entire doping range, the single
crystals exhibit an unusually broad and asymmetric distribution of hyperfine fields,
evidencing (local) magnetic cluster formation that persists to temperatures as high as
200 K, well above the glass transition reported from bulk magnetization. Above x(C)
the asymmetry decreases rapidly with increasing doping as magnetic clusters overlap
to give rise to long-range ferromagnetism. The key features of the spectra are
reproduced by a simple model in which Sr dopants trigger magnetic cluster formation.
Relaxation measurements at various locations in the magnetic clusters show the
correlation times of the fluctuating hyperfine fields becomes very slow on the edges
of a magnetic cluster due to large amounts of disorder. Below the MIT the system
is made of two regions, a) the very weakly magnetic regions outside a cluster where
Co3+ ions undergo spin-state transitions nearly identical to the parent compound,
and b) the disorder spin-glass regions made up of the magnetic clusters. The clusters
grow slowly with doping and see only a slowly changing density of states until they
begin to merge at x=0.10 where they grow rapidly and the carrier density drops.
(La,Sr)CuO(4): At intense magnetic fields (30 T) (17)O NMR exhibits two distinct
signatures for planar oxygen sites instead of the singular site expected from the identical
lattice symmetry at oxygen sites in the copper-oxygen plane for underdoped, orthorhombic
(La,Sr)CuO(4). Analysis of Knight shift, linewidth, quadrupolar splitting
and spectral asymmetry indicates that roughly 75% of the planar oxygens evidence
antiferromagnetically-correlated nearest neighbor Cu moments at temperatures below
∼30 K, consistent with previous reports. A second planar oxygen site first observed
in this study shows that there are mobile holes on roughly 25% of the planar oxygen
sites that (a) suppress magnetism for all T<300K and (b) show a Knight shift that
drops to zero below ∼60 K, evidencing pair formation at a temperature well above
the superconducting transition temperature (∼4 K at 30 T) and more than twice the
superconducting transition temperature at zero magnetic field.
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