Plasmonic scattering imaging of single CuSe nanoparticle for Hg detection.

The development of new efficient contrast nanoprobe has been greatly concerned in the field of scattering imaging for sensitive and accurate detection of trace analytes. In this work, the non-stoichiometric CuSe nanoparticle with typical localized surface plasmon resonance (LSPR) properties originating from their copper deficiency as a plasmonic scattering imaging probe was developed for sensitive and selective detection of Hg under dark-field microscopy. Hg can compete with Cu(I)/Cu(II) which were sources of optically active holes coexisting in these CuSe nanoparticles for its higher affinity with Se. The plasmonic properties of CuSe were adjusted effectively. Thus, the color scattering images of CuSe nanoparticles was changed from blue to cyan, and the scattering intensity was obviously enhanced with the dark-field microscopy. There was a linear relationship between the scattering intensity enhancement and the Hg concentration in the range of 10-300 nM with a low detection limit of 1.07 nM. The proposed method has good potential for Hg detection in the actual water samples. This work provides a new perspective on applying new plasmonic imaging probe for the reliable determination of trace heavy metal substances in the environment at a single particle level.