posted on 2022-01-05, 17:05authored byYunrui Han, Yingkuan Han, Jiayang Sun, Hong Liu, Xiaoming Luo, Yu Zhang, Lin Han
Surface-enhanced Raman scattering
(SERS) is widely used for low-concentration
molecular detection; however, challenges related to detection uniformity
and repeatability are bottlenecks for practical application, especially
as regards ultrasensitive detection. Here, through the coupling of
bionics and fluid mechanics, a lotus-leaf effect and rose-petal effect
(LLE–RPE)-integrated superhydrophobic chip is facilely developed
using laser-induced graphene (LIG) fabricated on a polyimide film.
Dense and uniform aggregation of gold nanoparticles (AuNPs) in droplets
is realized through a constant contact angle (CCA) evaporation mode
in the dynamic enrichment process, facilitating reliable ultrasensitive
detection. The detection chip consists of two components: an LLE zone
containing an ethanol-treated LIG superhydrophobic surface with a
low-adhesive property, which functions as an AuNP-controllable aggregation
zone, and an RPE zone containing an as-fabricated LIG superhydrophobic
surface with water-solution pinning ability, which functions as a
droplet solvent evaporation and a AuNP blending zone. AuNPs realize
uniform aggregation during rolling on the LLE zone, and then get immobilized
on the RPE zone to complete evaporation of the solvent, followed by
Raman detection. Here, based on dense and uniform AuNP aggregation,
the detection system achieves high-efficiency (242 s/18 μL)
and ultralow-concentration (10–17 M) detection of
a target analyte (rhodamine 6G). The proposed system constitutes a
simple approach toward high-performance detection for chemical analysis,
environmental monitoring, biological analysis, and medical diagnosis.