Superconducting spintronics with electron symmetry filtering and interfacial spin-orbit coupling

TL;DR

This paper reviews how electron symmetry filtering and interfacial spin-orbit coupling in superconductor-ferromagnet hybrids enable long-range spin-polarized supercurrents and triplet pairing, advancing superconducting spintronics technology.

Contribution

It highlights the role of crystalline MgO barriers and interfacial SOC in enabling symmetry mixing and triplet pairing in superconductor-ferromagnet devices.

Findings

Symmetry filtering enhances tunneling magnetoresistance.

Interfacial SOC enables conversion of singlet to triplet Cooper pairs.

Crystalline MgO barriers are crucial for selective electronic state transmission.

Abstract

Over the recent years, crossroads of magnetism and superconductivity led to the emerging field of superconducting spintronics. A cornerstone of this venture is the generation of equal-spin triplet Cooper pairs in superconductor-ferromagnet hybrids, enabling long-range spin-polarized supercurrents and magnetic control over superconducting quantum states for the development of energy-efficient cryogenic devices. Until now, nearly all superconducting spintronic devices have relied on direct interfaces between superconductors and ferromagnets, since it was believed that an insulating barrier would decouple spin and charge transport. This assumption, however, appears to be invalid when a thin spin- and orbit-filtering barrier couples epitaxial ferromagnet and the superconductor. Symmetry filtering plays a crucial role in enhancing giant tunneling magnetoresistance (TMR) by selectively allowing specific electronic states to tunnel through the barrier. Such a mechanism is key for high-performance spintronic devices like magnetic random access memories, magnetic sensors or spin-light emitting diodes. This manuscript provides a comprehensive review of superconducting spintronics driven by electron symmetry filtering and interfacial SOC. It emphasizes the critical role of a crystalline MgO barrier in selectively transmitting specific electronic states between V(100) and Fe(100). The manuscript also highlights how interfacial SOC enables symmetry mixing, allowing for the interaction between ferromagnetic and superconducting orderings though MgO(100). This mutual interaction, mediated by interfacial SOC, facilitates the conversion of spin-singlet to spin-triplet Cooper pairs. The work provides key insights into designing SOC based superconductor-ferromagnet hybrid structures for advanced superconducting spintronic functionalities.