Plasmonics Theory for Biosensor Design: Mathematical Formulations and Practical Applications
Mariam Moussilli, Abdul Rahman El Falou, Raed Shubair

TL;DR
This paper explores the mathematical foundations and practical uses of plasmonics nanotechnology for designing high-speed, miniaturized biosensors that leverage surface plasmon waves to monitor analyte concentrations in real-time.
Contribution
It provides new mathematical formulations and demonstrates practical applications of plasmonics for biosensor development, bridging electronic and photonic device technologies.
Findings
Enhanced understanding of plasmonic surface wave generation.
Design principles for miniaturized real-time biosensors.
Potential for high-speed, high-capacity on-chip biosensing applications.
Abstract
The last two decades have witnessed an exponential growth and tremendous developments in wireless technologies and systems, and their associated applications. In the recent years following 2006, there has been a great surge in interest in the newly emerging plasmonics nanotechnology because this new device technology provides tremendous synergy between electronic and photonic devices. Electronics devices are down-scalable up to the nanoscale size but have limited processor speed due to thermal and signal delay issues associated with electronic devices. On the other hand, photonic devices have extremely high speed and high data carrying capacity but are limited in size to the diffraction law such that the size of a photonic device should be equal to about half of its operational wavelength. The size mismatch between electronic devices and photonic devices inhibits the advantageous…
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Taxonomy
TopicsPlasmonic and Surface Plasmon Research · Photonic and Optical Devices · Advanced Fiber Optic Sensors
