A Novel Surface‐tethered Analysis Method for Mercury (II) ion Detection via Self‐assembly of Individual Electrochemiluminescence Signal Units

Abstract

AbstractA novel analysis strategy based on the analyte‐induced surface‐tethered (AIST) of electrochemiluminescence (ECL) signal nanoparticles was first proposed for detection of Mercury (II) ion (Hg2+). In this work, luminol@Au‐cysteamine‐thymine (luminol@Au‐Cys‐T) multifunctional nanoarchitecture was designed as ECL signal units in the experimental process. Through a specific T‐Hg2+‐T coordination, luminol@Au‐Cys‐T composites were gravitationally self‐assembled to the electrode surface, which was coated with tris (2‐aminoethyl) amine functionalized graphene oxide@perylene‐3,4,9,10‐tetracarboxylic acid‐thymine (GO@PTCA‐TAEA‐T) complex film. This simple strategy of AIST of signal molecules could amplify the response signal and vastly enhance the sensitivity. Under the optimum condition, the linear relationship of Hg2+ concentration variation from 0.005 nM to 5 nM with a limit of detection (LOD) down to 0.002 nM (S/N=3), which also offered an alternative analytical approach with excellent performance of stability and selectivity. The regression equation was y=−414.52+2305.02 lgC(Hg2+) (pM). This Hg2+ ECL sensor had a good application prospects for the analysis of real samples.