Optimal self-referenced sensing using long- and short- range surface plasmons | Zendy

J. Todd Hastings | Zendy; Jing Guo | Zendy; Phillip D. Keathley | Zendy; Prasanth Bathae Kumaresh | Zendy; Yinan Wei | Zendy; Stephanie Law | Zendy; Leonidas G. Bachas | Zendy

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Optimal self-referenced sensing using long- and short- range surface plasmons

Author(s) -

J. Todd Hastings,

Jing Guo,

Phillip D. Keathley,

Prasanth Bathae Kumaresh,

Yinan Wei,

Stephanie Law,

Leonidas G. Bachas

Publication year - 2007

Publication title -

optics express

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.394

H-Index - 271

ISSN - 1094-4087

DOI - 10.1364/oe.15.017661

Subject(s) - surface plasmon resonance , surface plasmon , optics , materials science , sensitivity (control systems) , plasmon , range (aeronautics) , reflectivity , resonance (particle physics) , optoelectronics , physics , nanotechnology , electronic engineering , atomic physics , engineering , nanoparticle , composite material

Dual-mode surface-plasmon resonance (SPR) sensors use both long- and short- range surface plasmon waves to differentiate surface binding interactions from interfering bulk effects. We have optimized the design of these sensors for minimum surface limit of detection (LOD) using a Cramer-Rao lower bound for spectral shift estimation. Despite trade-offs between resonance width, minimum reflectivity, and sensitivity for the two modes, a range of reasonable design parameters provides nearly optimal performance. Experimental verification using biotin-streptavidin binding as a model system reveals that sensitivity and LOD for dual-mode sensors remains competitive with single-mode sensors while compensating for bulk effects.

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