Location via proxy:   [ UP ]  
[Report a bug]   [Manage cookies]                

Crystalline Electric Field as a Probe for Long-Range Antiferromagnetic Order and Superconducting State of CeFeAsO1xFx

Songxue Chi, D. T. Adroja, T. Guidi, R. Bewley, Shiliang Li, Jun Zhao, J. W. Lynn, C. M. Brown, Y. Qiu, G. F. Chen, J. L. Lou, N. L. Wang, and Pengcheng Dai
Phys. Rev. Lett. 101, 217002 – Published 20 November 2008
PDFHTMLExport Citation
Abstract
Authors
Article Text
  • ACKNOWLEDGEMENTS
    • References

    Abstract

    We use inelastic neutron scattering to study the crystalline electric field (CEF) excitations of Ce3+ in CeFeAsO1xFx (x=0, 0.16). For nonsuperconducting CeFeAsO, the Ce CEF levels have three magnetic doublets in the paramagnetic state, but these doublets split into six singlets when the Fe ions order antiferromagnetically. For superconducting CeFeAsO0.84F0.16 (Tc=41K), where the static antiferromagnetic order is suppressed, the Ce CEF levels have three magnetic doublets at ω=0, 18.7, 58.4 meV at all temperatures. Careful measurements of the intrinsic linewidth Γ and the peak position of the 18.7 meV mode reveal a clear anomaly at Tc, consistent with a strong enhancement of local magnetic susceptibility χ(ω) below Tc. These results suggest that CEF excitations in the rare-earth oxypnictides can be used as a probe of spin dynamics in the nearby FeAs planes.

    • Figure
    • Figure
    • Figure
    • Figure
    • Received 31 July 2008

    DOI:https://doi.org/10.1103/PhysRevLett.101.217002

    ©2008 American Physical Society

    Authors & Affiliations

    Songxue Chi1, D. T. Adroja2, T. Guidi2, R. Bewley2, Shiliang Li1, Jun Zhao1, J. W. Lynn3, C. M. Brown3, Y. Qiu3,4, G. F. Chen5, J. L. Lou5, N. L. Wang5, and Pengcheng Dai1,6,*

    • 1Department of Physics and Astronomy, The University of Tennessee, Knoxville, Tennessee 37996-1200, USA
    • 2ISIS Facility, Rutherford Appleton Laboratory, Chilton, Didcot, Oxfordshire OX11 0QX, United Kingdom
    • 3NIST Center for Neutron Research, National Institute of Standards and Technology, Gaithersburg, Maryland 20899-6102, USA
    • 4Department of Materials Science and Engineering, University of Maryland, College Park, Maryland 20742, USA
    • 5Institute of Physics, Chinese Academy of Sciences, P. O. Box 603, Beijing 100080, China
    • 6Neutron Scattering Science Division, Oak Ridge National Laboratory, Oak Ridge, Tennessee 37831-6393, USA

    • *daip@ornl.gov

    Article Text (Subscription Required)

    Click to Expand

    References (Subscription Required)

    Click to Expand
    Issue

    Vol. 101, Iss. 21 — 21 November 2008

    Reuse & Permissions
    Access Options
    Author publication services for translation and copyediting assistance advertisement

    Authorization Required

    Log In
    Other Options
    ×

    Images

    • Figure 1
      Figure 1
      Summary of the CeFeAsO crystal or magnetic structure and CEF levels determined from our inelastic neutron scattering experiments. (a) The Fe spin ordering in the CeFeAsO chemical unit cell. (b) The Fe spins in CeFeAsO with respect to the Ce positions. The Fe moments lie in the ab plane along the a axis and form an antiferromagnetic collinear spin structure. (c) Ce3+ CEF levels in CeFeAsO for temperatures above and below the Fe AF Néel temperature of TN=140K [6]. The arrows indicate possible transitions. (d) Ce3+ CEF levels in superconducting CeFeAsO0.84F0.16 at low temperature.Reuse & Permissions
    • Figure 2
      Figure 2
      Temperature dependence of the CEF excitations in CeFeAsO and CeFeAsO0.84F0.16 integrated over 0<Q<4Å1 and our model determination of the CEF levels. (a) Ce CEF magnetic excitations in absolute units after subtracting the LaFeAsO phonons. The squares to the left denote the data with Ei=30.8meV to show the splitting. The solid line is our model fit with parameters listed in Table . The inset shows the raw DCS data integrated over 0<Q<2.2Å1 in arbitrary units as a function of temperature without the LaFeAsO phonon subtraction. (b) Ce CEF excitations at 200 K; solid line is our model calculation. (c–d) CEF excitations and their temperature dependence for CeFeAsO0.84F0.16. The solid lines are model calculations. Inset in (c) shows that the 0.7 meV excitation seen in CeFeAsO is missing in CeFeAsO0.84F0.16. Error bars represent 1 standard deviation.Reuse & Permissions
    • Figure 3
      Figure 3
      (a) Raw S(Q,ω) spectra of CeFeAsO at 60 K and Ei=30meV on MERLIN. (b) Ce CEF excitations after subtraction of the LaFeAsO background. (c) Temperature dependence of the 18.7 meV excitations. The peaks around 18 meV at 7 K are fitted with 2 Lorentzians, the widths of which were fixed for fittings at all higher temperatures. Although this ignores the broadening of linewidths upon warming and gives illusionary finite peak separation above TN, the net splitting solely caused by molecular field can be monitored by abrupt change of this separation which happens below 140 K, the TN of Fe as shown in (e).Reuse & Permissions
    • Figure 4
      Figure 4
      Temperature dependence of the ω1=18.7meV Ce CEF excitation for CeFeAsO0.84F0.16. (a) MERLIN measurements using Ei=30.8meV at different temperatures. The instrumental energy resolution is 2.1 meV at elastic position (horizontal bar). (b) The peak position as a function of temperature for the 18.7 meV CEF level. The solid squares are MERLIN data while light squares are FANS data; both show a clear anomaly at Tc. (c) The intrinsic linewidth Γ(T) as a function of temperature. The solid line shows the expected Γn(T) assuming noninteracting Fermi liquid. Γ(T) deviates from Γn(T) near Tc. (d) Γ(T)/Γn(T) shows a clear anomaly near Tc, consistent with (c).Reuse & Permissions
    ×

    Sign up to receive regular email alerts from Physical Review Letters

    Log In

    Cancel
    ×

    Search

    Article Lookup

    Paste a citation or DOI
    Enter a citation
    ×