NMR shift behavior of the planar Cu(1) site in the underdoped superconductor (formula presented)

J. H. Liversage, M. J.R. Hoch, J. M. Keartland, W. G. Moulton, Justin Schwartz, P. V.P.S.S. Sastry

Research output: Contribution to journalArticle

Abstract

(formula presented) hyperfine shift (Knight-shift) measurements have been carried out on the trilayered superconductor (formula presented) The temperature dependence of the in-plane Cu(1) Knight shift, for the fourfold oxygen coordinated Cu-O plane, clearly exhibits non-Fermi-liquid behavior. Our data has been placed in the context of the magnetic phase diagram of the nonlinear (formula presented) model, which highlights the various regions of magnetic scaling. In this way, evidence is obtained for the presence of a spin pseudogap in this Hg-based compound. This work also supports the suggestion of a nearly antiferromagnetic (AFM) Fermi liquid that dominates the magnetic shift and relaxation behaviors of the (formula presented) spins through an isotropic transferred coupling. To test the effects of the AFM enhancements on the Cu(1) spin-lattice relaxation rate, the ratio of the dynamical and static spin susceptibilities derived from relaxation and Knight-shift data is compared to that expected for materials having a transferred coupling of the Cu spins. There is a significant increase in the departure of this ratio from the expected value of 0.53, for an unperturbed transferred coupling scenario, with a drop in temperature below 300 K, suggesting an enhancement in the AFM fluctuations in this temperature region.

Original languageEnglish (US)
Pages (from-to)1-4
Number of pages4
JournalPhysical Review B - Condensed Matter and Materials Physics
Volume65
Issue number9
DOIs
StatePublished - Jan 1 2002

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Superconducting materials
Nuclear magnetic resonance
nuclear magnetic resonance
shift
Fermi liquids
Spin-lattice relaxation
Temperature
Phase diagrams
augmentation
spin-lattice relaxation
Oxygen
suggestion
phase diagrams
Liquids
magnetic permeability
scaling
temperature dependence
temperature
oxygen
liquids

All Science Journal Classification (ASJC) codes

  • Electronic, Optical and Magnetic Materials
  • Condensed Matter Physics

Cite this

Liversage, J. H. ; Hoch, M. J.R. ; Keartland, J. M. ; Moulton, W. G. ; Schwartz, Justin ; Sastry, P. V.P.S.S. / NMR shift behavior of the planar Cu(1) site in the underdoped superconductor (formula presented). In: Physical Review B - Condensed Matter and Materials Physics. 2002 ; Vol. 65, No. 9. pp. 1-4.
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abstract = "(formula presented) hyperfine shift (Knight-shift) measurements have been carried out on the trilayered superconductor (formula presented) The temperature dependence of the in-plane Cu(1) Knight shift, for the fourfold oxygen coordinated Cu-O plane, clearly exhibits non-Fermi-liquid behavior. Our data has been placed in the context of the magnetic phase diagram of the nonlinear (formula presented) model, which highlights the various regions of magnetic scaling. In this way, evidence is obtained for the presence of a spin pseudogap in this Hg-based compound. This work also supports the suggestion of a nearly antiferromagnetic (AFM) Fermi liquid that dominates the magnetic shift and relaxation behaviors of the (formula presented) spins through an isotropic transferred coupling. To test the effects of the AFM enhancements on the Cu(1) spin-lattice relaxation rate, the ratio of the dynamical and static spin susceptibilities derived from relaxation and Knight-shift data is compared to that expected for materials having a transferred coupling of the Cu spins. There is a significant increase in the departure of this ratio from the expected value of 0.53, for an unperturbed transferred coupling scenario, with a drop in temperature below 300 K, suggesting an enhancement in the AFM fluctuations in this temperature region.",
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NMR shift behavior of the planar Cu(1) site in the underdoped superconductor (formula presented). / Liversage, J. H.; Hoch, M. J.R.; Keartland, J. M.; Moulton, W. G.; Schwartz, Justin; Sastry, P. V.P.S.S.

In: Physical Review B - Condensed Matter and Materials Physics, Vol. 65, No. 9, 01.01.2002, p. 1-4.

Research output: Contribution to journalArticle

TY - JOUR

T1 - NMR shift behavior of the planar Cu(1) site in the underdoped superconductor (formula presented)

AU - Liversage, J. H.

AU - Hoch, M. J.R.

AU - Keartland, J. M.

AU - Moulton, W. G.

AU - Schwartz, Justin

AU - Sastry, P. V.P.S.S.

PY - 2002/1/1

Y1 - 2002/1/1

N2 - (formula presented) hyperfine shift (Knight-shift) measurements have been carried out on the trilayered superconductor (formula presented) The temperature dependence of the in-plane Cu(1) Knight shift, for the fourfold oxygen coordinated Cu-O plane, clearly exhibits non-Fermi-liquid behavior. Our data has been placed in the context of the magnetic phase diagram of the nonlinear (formula presented) model, which highlights the various regions of magnetic scaling. In this way, evidence is obtained for the presence of a spin pseudogap in this Hg-based compound. This work also supports the suggestion of a nearly antiferromagnetic (AFM) Fermi liquid that dominates the magnetic shift and relaxation behaviors of the (formula presented) spins through an isotropic transferred coupling. To test the effects of the AFM enhancements on the Cu(1) spin-lattice relaxation rate, the ratio of the dynamical and static spin susceptibilities derived from relaxation and Knight-shift data is compared to that expected for materials having a transferred coupling of the Cu spins. There is a significant increase in the departure of this ratio from the expected value of 0.53, for an unperturbed transferred coupling scenario, with a drop in temperature below 300 K, suggesting an enhancement in the AFM fluctuations in this temperature region.

AB - (formula presented) hyperfine shift (Knight-shift) measurements have been carried out on the trilayered superconductor (formula presented) The temperature dependence of the in-plane Cu(1) Knight shift, for the fourfold oxygen coordinated Cu-O plane, clearly exhibits non-Fermi-liquid behavior. Our data has been placed in the context of the magnetic phase diagram of the nonlinear (formula presented) model, which highlights the various regions of magnetic scaling. In this way, evidence is obtained for the presence of a spin pseudogap in this Hg-based compound. This work also supports the suggestion of a nearly antiferromagnetic (AFM) Fermi liquid that dominates the magnetic shift and relaxation behaviors of the (formula presented) spins through an isotropic transferred coupling. To test the effects of the AFM enhancements on the Cu(1) spin-lattice relaxation rate, the ratio of the dynamical and static spin susceptibilities derived from relaxation and Knight-shift data is compared to that expected for materials having a transferred coupling of the Cu spins. There is a significant increase in the departure of this ratio from the expected value of 0.53, for an unperturbed transferred coupling scenario, with a drop in temperature below 300 K, suggesting an enhancement in the AFM fluctuations in this temperature region.

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