Spin-glass behavior in KxRu4-yNiyO8 hollandite materials

Journal article


Vera-Stimpson, L. 2018. Spin-glass behavior in KxRu4-yNiyO8 hollandite materials. Physical Review B (PRB). 98 (17). https://doi.org/10.1103/PhysRevB.98.174429
AuthorsVera-Stimpson, L.
Abstract

We report the synthesis and comprehensive ac and dc susceptibility measurements of KxRu4−yNiyO8 hollandite. The value of the relative frequency shift, δTf , has been determined as 0.025 which is within the range expected for spin-glass systems (0.005–0.06). Additionally, the characteristic flipping time of a single spin flip, τ0, and the dynamical critical exponent, −zv, were determined to have values of 5.82×10−8 s and 6.1(3), respectively from the power law. While the value of τ0 is comparatively very large, −zv is consistent with what is expected for spin-glass systems. Field-cooled hysteresis behavior demonstrates a small increase in the remnant magnetization (at 2 K) on increasing the strength of the cooling field, suggesting that the degree of short-range correlations increases consistent with the formation of larger spin clusters. Thermoremnant magnetization data indicate an exponential-like decay of the magnetization as a function of time with the remnant magnetization remaining nonzero. However, it is clear from these data that multiple components contribute to the decay behavior. Collectively, these data confirm spin-glass character for K0.73(3)Ni1.9(5)Ru2.1(5)O8 and clearly demonstrate that the magnetic behavior of this material is far from simplistic.

Year2018
JournalPhysical Review B (PRB)
Journal citation98 (17)
PublisherAmerican Physical Society
Digital Object Identifier (DOI)https://doi.org/10.1103/PhysRevB.98.174429
Publication dates
Print26 Nov 2018
Publication process dates
Deposited30 Nov 2018
Accepted30 Oct 2018
Accepted author manuscript
Output statusPublished
ContributorsPowell, J., Stenning, G., Jura, M. and Arnold, D.
Permalink -

https://repository.canterbury.ac.uk/item/88xxy/spin-glass-behavior-in-kxru4-yniyo8-hollandite-materials

  • 67
    total views
  • 177
    total downloads
  • 1
    views this month
  • 0
    downloads this month

Export as

Related outputs

Development of a radiographic technique for porcine head ballistic research
Brooke, N., Elliott, J., Murphy, T. and Vera-Stimpson, L. 2023. Development of a radiographic technique for porcine head ballistic research. Radiography. 29 (6), pp. 980-983. https://doi.org/10.1016/j.radi.2023.08.001
Phase stability of the layered oxide, Ca2Mn3O8: probing the pressure-temperature phase diagram
Vera-Stimpson, L., Etherdo-Sibley K. J., Ridley C. J., Bull C. L. and Arnold D. C 2020. Phase stability of the layered oxide, Ca2Mn3O8: probing the pressure-temperature phase diagram. Materials Advances. 1 (6), pp. 1841 - 1848. https://doi.org/10.1039/D0MA00464B
A comprehensive variable temperature study of the layered oxide Ca2Mn3O8
Vera-Stimpson, L.J., McNulty, J.A., Morrison, F.D., Mahajan, A., McCabe, E.E., Gibbs, A.S., Stenning, G.B.G., Jura, M. and Arnold, D.C. 2020. A comprehensive variable temperature study of the layered oxide Ca2Mn3O8. Journal of Alloys and Compounds. https://doi.org/10.1016/j.jallcom.2020.155633
PZT-like structural phase transitions in the BiFeO3-KNbO3 solid solution
Lennox, R., Taylor, D., Vera-Stimpson, L., Stenning, G., Jura, M., Price, M., Rodriguez, E. and Arnold, D. 2015. PZT-like structural phase transitions in the BiFeO3-KNbO3 solid solution. Dalton Transactions. https://doi.org/10.1039/C5DT00140D
Investigation of the role of morphology on the magnetic properties of Ca2Mn3O8 materials
Vera-Stimpson, L., Ramos, S., Stenning, G., Jura, M. and Arnold, D. 2017. Investigation of the role of morphology on the magnetic properties of Ca2Mn3O8 materials. Dalton Transactions. 41. https://doi.org/10.1039/C7DT03053C
Magnetic ordering in a frustrated bow-tie lattice
Vera-Stimpson, L., Rodriguez, E., Brown, C., Stenning, G., Jura, M. and Arnold, D. 2018. Magnetic ordering in a frustrated bow-tie lattice. Journal of Materials Chemistry C. https://doi.org/10.1039/C7TC05187E