Bismuth kagome sublattice distortions by quenching and flux pinning in superconducting ${\mathrm{RbBi}}_{2}$

Bismuth kagome sublattice distortions by quenching and flux pinning in superconducting ${RbBi}_{2}$

Sharon S. Philip, Junjie Yang, Despina Louca, P. F. S. Rosa, J. D. Thompson, and K. L. Page

Phys. Rev. B 104, 104503 – Published 8 September 2021

Abstract

The properties of ${RbBi}_{2}$ , a 4.15 K superconductor, were investigated using magnetic field, pressure, and neutron diffraction. Under hydrostatic pressure, an almost 50% reduction of $T_{c}$ is observed, linked to a low Debye temperature estimated at 165 K. The resistivity and magnetic susceptibility were measured on quenched and slow-cooled polycrystalline samples. The resistivity follows a low temperature power-law dependence in both types of samples, while the diamagnetic susceptibility, $χ$ , is dependent on the sample cooling history. Slow-cooled samples have $χ = - 1$ while quenched samples have $χ < - 1$ due to grain size differences. Evidence of the effects of the cooling rate is also discerned from the local structure, obtained by neutron diffraction and the pair density function analysis. Slow-cooled samples have structurally symmetric Bi hexagons, in contrast to quenched samples in which disorder is manifested in periodic distortions of the Bi hexagonal rings of the kagome sublattice. Disorder may lead to flux pinning that reduces vortex mobility, but $T_{c}$ remains unaffected by the cooling rate.

Received 4 June 2021
Revised 23 July 2021
Accepted 20 August 2021

DOI:https://doi.org/10.1103/PhysRevB.104.104503

Physics Subject Headings (PhySH)

Flux pinning Pressure effects Superconductivity

Kagome lattice

Condensed Matter, Materials & Applied Physics

Authors & Affiliations

Sharon S. Philip , Junjie Yang^2,*, and Despina Louca^3,†

Department of Physics, University of Virginia, Charlottesville, Virginia 22904, USA

P. F. S. Rosa and J. D. Thompson³

Los Alamos National Laboratory, Los Alamos, New Mexico 87545, USA

K. L. Page

Department of Materials Science and Engineering, The University of Tennessee, Tennessee 37996, USA

^*Current address: Department of Physics, New Jersey Institute of Technology, Newark, New Jersey 07102, USA.
^†louca@virginia.edu

Article Text (Subscription Required)

Click to Expand

References (Subscription Required)

Click to Expand

Issue

Vol. 104, Iss. 10 — 1 September 2021

Reuse & Permissions

Access Options

Article Available via CHORUS

Download Accepted Manuscript

Author publication services for translation and copyediting assistance advertisement

Images

Figure 1
(a) The neutron powder diffraction pattern of as-grown (AG), slow-cooled ${RbBi}_{2}$ collected at 2 K is fit with a cubic model that fits the data quite well. Shown in the inset is a model of the crystal structure. (b) The temperature dependence of the lattice constant determined from the Rietveld refinement. (c) The isotropic thermal factors for Rb and Bi in both AG and Quenched (Q) ${RbBi}_{2}$ . (d) The $G (r)$ function determined for AG ${RbBi}_{2}$ at 2 K is compared to a model $G (r)$ with the $F d \bar{3} m$ symmetry. (e) A comparison of the $G (r)$ for AG and Q samples of ${RbBi}_{2}$ obtained from the diffraction data collected at 200 K and plotted from 50 to 100 Å. The difference curve is shown below the data. The differences, although small, are attributed to the Bi sublattice distortions shown in the middle of the figure. This is deduced from the partial PDFs of the three pair correlations, Bi-Bi, Bi-Rb, and Rb-Rb that are plotted below. These partials are determined from the model fitting of the 200 K AG data.
Reuse & Permissions
Figure 2
(a) The electrical resistivity showing superconducting transition in the presence of applied field for ${RbBi}_{2}$ below the critical field. (b) The resistivity as a function of temperature for AG sample of ${RbBi}_{2}$ in the absence of magnetic field. The resistivity of the quenched sample is shown in the inset. (c) The low temperature resistivity fitted with power law relation with temperature $ρ = A + B T^{n}$ with $n = 2.91$ . The solid line shows the fitting. (d) The temperature dependence of squared FWHM values of the first peak of the local structural data of ${RbBi}_{2}$ , extracted from a Gaussian fitting. The fit of correlated Debye model is represented by the solid line. All the measurements were done on the AG sample.
Reuse & Permissions
Figure 3
The magnetic characterization of AG [(a), (b), (c), (e)] and Q [(b), (d), (e)] ${RbBi}_{2}$ . Shown in (a) is the bulk susceptibility, $χ$ , for the AG sample as a function of field. Shown in (b) is the comparison of bulk susceptibility for the AG and Q samples. Shown in (c) and (d) are magnetization curves, $M (H)$ , after the demagnetization correction for the AG and Q samples, respectively. Very little hysteresis is observed in the AG M(H) unlike in the Q sample. Shown in (e) is the critical magnetic fields of AG and Q samples of ${RbBi}_{2}$ obtained from the magnetization isotherms. The dashed lines represent a fit to the data. Shown in (f) is the behavior of superconducting transition temperature of AG ${RbBi}_{2}$ in the presence of applied pressure. The dashed line shows the quadratic fit on the pressure dependence of $T_{c}$ .
Reuse & Permissions

Physical Review B

covering condensed matter and materials physics

Bismuth kagome sublattice distortions by quenching and flux pinning in superconducting ${RbBi}_{2}$

Sharon S. Philip, Junjie Yang, Despina Louca, P. F. S. Rosa, J. D. Thompson, and K. L. Page

Phys. Rev. B 104, 104503 – Published 8 September 2021

Abstract

Physics Subject Headings (PhySH)

Authors & Affiliations

Article Text (Subscription Required)

References (Subscription Required)

Issue

Access Options

Physical Review B

covering condensed matter and materials physics

Bismuth kagome sublattice distortions by quenching and flux pinning in superconducting RbBi2

Sharon S. Philip, Junjie Yang, Despina Louca, P. F. S. Rosa, J. D. Thompson, and K. L. Page

Phys. Rev. B 104, 104503 – Published 8 September 2021

Abstract

Physics Subject Headings (PhySH)

Authors & Affiliations

Article Text (Subscription Required)

References (Subscription Required)

Issue

Access Options

Authorization Required

Other Options

Download & Share

Images

Figure 1

Figure 2

Figure 3

Log In

Search

Article Lookup

Paste a citation or DOI

Enter a citation

Bismuth kagome sublattice distortions by quenching and flux pinning in superconducting ${RbBi}_{2}$