Ferromagnetic Nanowires for Nonreciprocal Millimeter-Wave Applications: Investigations of Artificial Ferrites for Realizing High-Frequency Communication Components

“…Magnetic resonance spectroscopy is developed based on the traditional radiofrequency (RF) identification method, which uses the AC magnetic field of a radio-frequency signal, in the either presence or absence of a DC magnetic field, to sense the magnetic nanobarcodes. By varying the DC magnetic field, the resonance frequency of the MNWs change, and that can be used as an extra degree of freedom for secure sensing [ 129 ]. Magnetic resonance spectroscopy could be faster compared to the DC measurements for sensing.…”

Magnetic Nanowires for Nanobarcoding and Beyond

“…Magnetic resonance spectroscopy is developed based on the traditional radiofrequency (RF) identification method, which uses the AC magnetic field of a radio-frequency signal, in the either presence or absence of a DC magnetic field, to sense the magnetic nanobarcodes. By varying the DC magnetic field, the resonance frequency of the MNWs change, and that can be used as an extra degree of freedom for secure sensing [ 129 ]. Magnetic resonance spectroscopy could be faster compared to the DC measurements for sensing.…”

Magnetic Nanowires for Nanobarcoding and Beyond

“…Recent progress in engineered materials with novel electromagnetic properties is paving the way for technological advances on several fronts, ranging from nonreciprocal devices [1][2][3][4][5][6] to hyperbolic metamaterials [7] and photonic Chern insulators [8]. Three major electromagnetic wave phenomena, namely the (i) nonreciprocity, (ii) photonic spin, and (iii) hyperbolic topology, are at the forefront of next-generation devices, with all three posing unique challenges and opportunities.…”

Spin-governed topological surfaces and broken spin-momentum locking in a gyromagnetic medium

Solid-state synthesis of heterogeneous Ni0.5Cu0.5-xZnxFe2O4 spinel oxides with controlled morphology and tunable dielectric properties