Ivan Hrvoic scite author profile

The magneto-optic (MO) characteristics and sensing performance of noble metal (Ag, Au, Cu) or transition metal (Fe, Ni, Co) single layers and Ag/Co or Au/Co bilayers have been studied and compared in both the standard plasmonic and MO plasmonic configurations at two different wavelengths (632.8 nm and 785 nm) and in two different sensing media (air and water). The sensing performance is found to be medium-specific and lower in biosensor-relevant water-based media. The sensitivities of MO-SPR sensors is found to be superior to SPR sensors in all cases. This enhancement in sensitivity means the detection limit of this class of transducers can be substantially improved by tuning Au/Co layer thickness, wavelength, and incident angle of optical radiation. The optimized bilayer showed an enhancement in sensitivity by over 30× in air and 9× in water as compared to the conventional Au SPR configuration. Notably, the best performance is 3× above that of MO-SPR sensors coupled to a photonic crystal previously reported in the literature and is found when the ferromagnetic layer is furthest from the sensing medium, as opposed to typical MO-SPR configurations. This proposed structure is attractive for next-generation biosensors.

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New, stable β-phosphorus-labelled pyrrolidine nitroxides from nitrones for magnetometry: an ESR investigation

Haire¹,

Janzen²,

Chen³

et al. 1999

Magn. Reson. Chem.

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Microstructure and magneto-optical surface plasmon resonance of Co/Au multilayers

Rizal

Pisana

Hrvoic³

et al. 2018

J. Phys. Commun.

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Magneto-optical surface plasmon resonance (MOSPR) sensors benefit from a magneto-optic enhancement with respect to surface plasmon resonance (SPR) sensors, making these devices attractive for biosensing applications. Typical design compromises seek to balance magneto-optic effects and optical losses associated with surface plasmon waves extending to the ferromagnetic layer. Here, we demonstrate that Co/Au multilayers can yield sizeable MOSPR improvements in spite of the relative high total Co layer thickness. Co (t Co )/Au (2 nm) multilayers, with 1.2t Co 1.8 nm are prepared and characterized. X-ray analysis shows that the microstructure maintains high layer periodicity and improves upon annealing. The multilayer structures were then modeled to study their SPR/MOSPR sensitivities, suggesting that the MOSPR sensitivity is enhanced by a factor of up to 3 and 4 with respect to the SPR sensitivity when the devices are operated in Air and Water media, respectively. We find that multilayers provide a particular advantage when operating the sensors in Water-based media.

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Instruments and Methodologies for Measurement of the Earth’s Magnetic Field

Hrvoic¹,

Newitt

2010

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Geophysical applications

Prouty¹,

Johnson²,

Hrvoic³

et al. 2013

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Ivan Hrvoic

Improved Magneto-Optic Surface Plasmon Resonance Biosensors

New, stable β-phosphorus-labelled pyrrolidine nitroxides from nitrones for magnetometry: an ESR investigation

Microstructure and magneto-optical surface plasmon resonance of Co/Au multilayers

Instruments and Methodologies for Measurement of the Earth’s Magnetic Field

Geophysical applications

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