Polarized neutron imaging and three-dimensional calculation of magnetic flux trapping in bulk of superconductors

Abstract: Polarized neutron radiography was used to study the 3D magnetic flux distribution inside of single crystal and polycrystalline Pb cylinders with large (cm 3 ) volume and virtually zero demagnetization.Experiments with single crystals being in the Meissner phase (T Show more

“…Experimentally, in addition to various macroscopic and indirect techniques, magnetic flux structures in type-I superconductors were visualized on the sample surface by using a Bi wire as a magnetoresistive probe, 30,31 by decoration with small diamagnetic 32 or ferromagnetic [33][34][35] particles, by the electron mirror technique, 36 by using the magneto-optical Faraday effect, 10,14,16,26,[37][38][39] by using miniature scanning Hall probes 40,41 and, in the bulk, by using polarized neutron reflectometry 42,43 and muon spin rotation. 44 Unlike type-II superconductors where the magnetic field can appear only in the form of single-flux-quantum Abrikosov vortices, 45 the mix of normal and superconducting domains in the intermediate state of type-I superconductors exhibits diverse geometric patterns, and their shape and distribution depend sensitively on many factors, including chemical, mechanical and geometrical parameters of the studied samples, 9,23,26,46 history of how magnetic fields and temperature were varied, direction of the magnetic field with respect to the sample, and dynamical perturbations such as electric currents or ac fields.…”

Equilibrium intermediate-state patterns in a type-I superconducting slab in an arbitrarily oriented applied magnetic field

“…Experimentally, in addition to various macroscopic and indirect techniques, magnetic flux structures in type-I superconductors were visualized on the sample surface by using a Bi wire as a magnetoresistive probe, 30,31 by decoration with small diamagnetic 32 or ferromagnetic [33][34][35] particles, by the electron mirror technique, 36 by using the magneto-optical Faraday effect, 10,14,16,26,[37][38][39] by using miniature scanning Hall probes 40,41 and, in the bulk, by using polarized neutron reflectometry 42,43 and muon spin rotation. 44 Unlike type-II superconductors where the magnetic field can appear only in the form of single-flux-quantum Abrikosov vortices, 45 the mix of normal and superconducting domains in the intermediate state of type-I superconductors exhibits diverse geometric patterns, and their shape and distribution depend sensitively on many factors, including chemical, mechanical and geometrical parameters of the studied samples, 9,23,26,46 history of how magnetic fields and temperature were varied, direction of the magnetic field with respect to the sample, and dynamical perturbations such as electric currents or ac fields.…”

Equilibrium intermediate-state patterns in a type-I superconducting slab in an arbitrarily oriented applied magnetic field

“…However, typical IS domain sizes of several µm are not accessible by standard scattering techniques such as small-angle neutron scattering (SANS). Moreover, polarized neutron radiography [14], which has been used for the imaging of trapped flux in SCs, is lacking resolution for a detailed study of the IS structure [15].…”

Neutron Dark-Field Imaging of the Domain Distribution in the Intermediate State of Lead

“…The neutron's non-destructive nature along with its deep penetration makes PNI a unique technique for studying magnetic fields inside samples. 5,6 This technique has been implemented at several neutron imaging beamlines. 7,8 The behavior of the neutron polarization in a magnetic field is described by the Bloch equation,…”

Improving polarized neutron imaging for visualization of the Meissner effect in superconductors