Atomic origin of the coexistence of high critical current density and high Tc in CuBa2Ca3Cu4O10+δ superconductors

For cuprate superconductors, a high critical transition temperature (T-c) can be realized in compounds containing multiple CuO2 layers in the unit cell, while a high critical current density (J(c)) is rarely sustained above liquid nitrogen temperature. The CuBa2Ca3Cu4O10+delta (Cu-1234) superconductors synthesized under high oxygen pressure incredibly exhibit high T-c (similar to 117 K) and high J(c) (>10(4) A/cm(2), 100K) values. Here, the double high traits of Cu-1234 were investigated with advanced scanning transmission electron microscopy. It was revealed that ordering vacancies and plate-like 90 degrees microdomains induced efficient microstructure pinning centers that suppressed vortex flux flow and enhanced J(c). Furthermore, metallic charge-reservoir blocks [Ba2CuO3+delta] were composed of unique compressed [CuO6] octahedra, which induced many holes with 2p(z) symmetry that significantly decreased the superconducting anisotropy and dramatically enhanced the interlayer coupling that guaranteed a high J(c). On the other hand, optimally doped CuO2 planes inside the thick superconducting blocks [Ca3Cu4O8] maintained a high Our results are applicable to design and synthesis of new superconductors with double high traits.

Automated summary

This study reveals the mechanisms behind the double high traits of Cu-1234 superconductors: ordered vacancies and plate-like microdomains enhance Jc, while metallic charge-reservoir modules composed of [CuO6] octahedra reduce superconducting anisotropy and enhance interlayer coupling. These findings have significant implications for the design and synthesis of new superconductors with double high traits.