<p>This study investigates the influence of grain boundary geometry on superconducting performance in Bi-2223 polycrystalline samples subjected to different uniaxial compaction pressures. Samples prepared by solid-state reaction were compacted at 148&#xa0;MPa (low-pressure sample), 199&#xa0;MPa (medium-pressure sample), and 248&#xa0;MPa (high-pressure sample). SEM micrographs were examined using multiscale fractal analysis combined with a refined region of interest protocol designed to exclude edge artifacts. Increasing compaction enhanced superconducting performance, with <i>J</i><sub><i>c</i></sub>(0) rising from 293 to 547&#xa0;A/cm<sup>2</sup>, residual resistivity <i>ρ</i><sub><i>0</i></sub> decreasing from 1.06 to 0.76&#xa0;mΩ&#xa0;cm, and texture factor <i>F</i><sub>(00<i>&#xa0;l</i>)</sub> increasing from 0.63 to 0.70. ROI-based analysis revealed a systematic reduction of the grain boundary fractal dimension <i>D</i><sub>gb</sub> from 1.483 ± 0.067 (powder) to 1.285 ± 0.047 (high-pressure sample), while no statistical difference was observed between the low- and medium-pressure samples; <i>log</i>(<i>B</i>), <i>D</i><sub><i>2</i></sub>, and log-transformed unit scale lacunarity <i>log</i>(<i>Λ</i><sub><i>1</i></sub>) exhibited the same invariance before changing significantly at the highest pressure. These results demonstrate that interface geometry evolves under pressure in a threshold-dependent rather than continuous manner, with a geometric invariance regime between 148 and 199&#xa0;MPa followed by a statistically significant transition at 248&#xa0;MPa. Strong correlations between fractal descriptors and transport parameters confirm that multiscale fractal analysis provides a sensitive, nondestructive probe of the critical geometric thresholds governing granular Bi-2223 superconductivity.</p>

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Fractal geometry as a descriptor of superconducting performance in Bi-2223 samples

  • Ivan García-Fornaris,
  • Humberto Millán,
  • Ernesto Govea-Alcaide

摘要

This study investigates the influence of grain boundary geometry on superconducting performance in Bi-2223 polycrystalline samples subjected to different uniaxial compaction pressures. Samples prepared by solid-state reaction were compacted at 148 MPa (low-pressure sample), 199 MPa (medium-pressure sample), and 248 MPa (high-pressure sample). SEM micrographs were examined using multiscale fractal analysis combined with a refined region of interest protocol designed to exclude edge artifacts. Increasing compaction enhanced superconducting performance, with Jc(0) rising from 293 to 547 A/cm2, residual resistivity ρ0 decreasing from 1.06 to 0.76 mΩ cm, and texture factor F(00 l) increasing from 0.63 to 0.70. ROI-based analysis revealed a systematic reduction of the grain boundary fractal dimension Dgb from 1.483 ± 0.067 (powder) to 1.285 ± 0.047 (high-pressure sample), while no statistical difference was observed between the low- and medium-pressure samples; log(B), D2, and log-transformed unit scale lacunarity log(Λ1) exhibited the same invariance before changing significantly at the highest pressure. These results demonstrate that interface geometry evolves under pressure in a threshold-dependent rather than continuous manner, with a geometric invariance regime between 148 and 199 MPa followed by a statistically significant transition at 248 MPa. Strong correlations between fractal descriptors and transport parameters confirm that multiscale fractal analysis provides a sensitive, nondestructive probe of the critical geometric thresholds governing granular Bi-2223 superconductivity.