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Intertwined symmetry of the magnetic modulation and the flux-line lattice in the superconducting state of TmNi2B2C

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Abstract

Materials that can in principle exhibit both superconductivity and ferromagnetism are caught in a dilemma: both states represent long-range order, but are in general mutually exclusive. When the material favours a ground state with a large magnetic moment, as is the case for Er4Rh4B (ref. 1), superconductivity is destroyed. For superconductivity to persist, the magnetic structure would need to adopt an antiferromagnetic modulation of short enough wavelength to ensure a small net moment on the length scale of the superconducting coherence length. The intermetallic borocarbide superconductors2,3,4 RNi2B2C (where R is a rare-earth element) have shed new light on this balance between magnetism and superconductivity. The response of these materials in the superconducting state to a magnetic field is dominated by the formation of a flux-line lattice—a regular array of quantized magnetic vortices whose symmetry and degree of order are easily modified and thus can be expected to interact with an underlying magnetic modulation. In TmNi2B2C, superconductivity and antiferromagnetic modulated ordering coexist below 1.5 K (57). Here we present the results of a small-angle neutron-scattering study of this compound which show that the structure of the magnetic modulation and the symmetry of the flux-line lattice are intimately coupled, resulting in a complex phase diagram.

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Figure 1: The magnetic phase diagram for TmNi2B2C.
Figure 2: The temperature dependence of the integrated reflectivity R for the FLL at several different magnetic fields between 1 and 5 kOe.
Figure 3: The different FLL structures observed in Tm:1221.
Figure 4: The low-temperature composite phase diagram, including bulk superconductivity, the FLL symmetry and magnetic phases in Tm:1221.

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Acknowledgements

We thank C. Stassis, P. Hedegård and J. Jensen for discussions. This work was supported by NATO. M.R.E. is supported by the Danish Research Academy, D.G.N. is supported by the Robert A. Welch Foundation and P.C.C. is supported by the Director of Energy Research, Office of Basic Energy Science.

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Authors and Affiliations

  1. Ris National Laboratory, PO Box 49, Roskilde, DK-4000, Denmark

    M. R. Eskildsen, A. B. Abrahamsen, N. H. Andersen & K. Mortensen

  2. Advanced Research Laboratory, Hitatchi Ltd, Hatoyama, 350-03, Saitama, Japan

    K. Harada

  3. Bell Laboratories, Lucent Technologies, 700 Mountain Avenue, Murray Hill, 07974, New Jersey, USA

    P. L. Gammel, G. Ernst, A. P. Ramirez & D. J. Bishop

  4. Physics Department, Texas A&M University, College Station, Texas, 77843, USA

    D. G. Naugle & K. D. D. Rathnayaka

  5. Ames Laboratory and Department of Physics and Astronomy, Iowa State University, Ames, 50011, Iowa, USA

    P. C. Canfield

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  1. M. R. Eskildsen
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  2. K. Harada
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  3. P. L. Gammel
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  4. A. B. Abrahamsen
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  5. N. H. Andersen
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  6. G. Ernst
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  7. A. P. Ramirez
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  8. D. J. Bishop
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  9. K. Mortensen
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  10. D. G. Naugle
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  11. K. D. D. Rathnayaka
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  12. P. C. Canfield
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Correspondence to M. R. Eskildsen.

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Eskildsen, M., Harada, K., Gammel, P. et al. Intertwined symmetry of the magnetic modulation and the flux-line lattice in the superconducting state of TmNi2B2C. Nature 393, 242–245 (1998). https://doi.org/10.1038/30447

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