A Field-Weighted model for Surface Layer Characterization using Single Channel Intensity Interrogation SPR

TL;DR

This paper introduces a field-weighted analysis method for SPR that accurately characterizes surface layer thickness and refractive index using a simple intensity interrogation technique, improving practicality and precision.

Contribution

The study develops a novel field-weighted model that separates bulk and surface responses in SPR, enabling accurate, simultaneous measurement of surface layer parameters without complex optical setups.

Findings

Accurately measured RI of BSA solutions with maximum error 0.0004.

Surface BSA layer parameters matched reported values.

Method simplifies SPR setup, making it suitable for portable applications.

Abstract

To address the difficulty of characterizing the surface layer rigorously, especially the thickness and refractive index (RI) in surface plasmon resonance (SPR) technology, we propose a field-weighted analysis method. This approach enables simultaneous quantitative determination of RI for the bulk solution and the surface layer. This study utilizes the aluminum-based Kretschmann structure with the intensity interrogation technique. We construct the field-weighted model governed by the evanescent field penetration depth to decompose the SPR reflected intensity into the bulk and surface responses. Experiments are conducted using bovine serum albumin (BSA) solution to form a surface adsorbed protein layer, and different concentrations of BSA are tested. Results show that the separated surface response fits well with the Langmuir formula, representing a significant improvement over the untreated SPR signal. The bulk and surface responses are then incorporated into the field-weighted model to determine the RI values of the bulk BSA solution and the surface adsorbed BSA layer at various concentrations. The experimental results of BSA solution match the Abbe refractometer measurements with a maximum error 0.0004 in RI, while the results of the adsorbed BSA layer, both the RI and thickness, aligned well with reported parameters for a single BSA layer. This method eliminates the stage rotation in the common angular interrogation SPR technique and complicated optical design and nano-fabrication in the nano-optics sensing schemes, making it suitable for compact, low-cost SPR platforms for practical applications needing surface layer characterization.