Self-biased coplanar circulator based on electrochemically grown ferrimagnetic nanowires

This paper is about a self-biased coplanar circulator. The design approach is based on the use of magnetic composite substrates self-polarized made from ferrimagnetic nanowires. It consists of integrating and orienting cobalt ferrite (CoFe2O4) nanocrystallites in porous alumina membrane using the magneto-electrodeposition technique. XRD, SEM and EDX analysis confirmed the formation of the spinel phase of cobalt ferrite with a good distribution of Co, Fe and O elements in the unit cell of CoFe2O4 nanowires. The performed SQUID-VSM measurements have revealed that the nano-composite electrodeposited and cooled under a magnetic field of 0.6 T has the best magnetic properties, i.e. a large anisotropy field (Ha), moderate coercive field (Hc), and partial squareness ratio (Mr/Ms). This nano-composite has been selected as an interesting candidate for the fabrication of a miniaturized self-biased circulator. The study has started with the implementation of an analytical dimensioning process based on Bosma's theory. Based on interesting HFSS simulation results, a first prototype was fabricated in the clean room and characterized at high frequencies. The measurements of the S parameters have highlighted a circulation phenomenon of 3 dB.

Automated summary

This paper presents the design and fabrication of a self-biased coplanar circulator using magnetic composite substrates and magneto-electrodeposition technique. The experimental and simulation results demonstrate the successful implementation of a prototype with a circulation phenomenon of 3 dB, highlighting the excellent magnetic properties of the composite material.