Lanthanide magneto-luminescent and plasmonic (Gd2O3:Eu@AuNR) nanoassembly for the turn-on fluorescence detection of nitro aromatic compound

  • G. L. Praveen
  • G. M. Lekha
  • V. M. Visakh
  • L. R. Reshma
  • Sony George
Research Paper
First Online:
Received:
Accepted:

Abstract

In this study, we design a nanoassembly-based chemosensor possessing the fluorescence in the visible region which comes into play for analyte detection in aqueous medium. Here, Mercaptopropionic acid-functionalised nanophosphor (Gd2O3:Eu @ MPA) acts as donor, and the Cysteamine functionalised gold nanorod (AuNR @ Cysteamine) acts as the acceptor molecule. The working principle of this nanoassembly is the FRET phenomenon which happens between nanophosphors and gold nanorods through amine-carboxyl attractive interactions (Turn-Off) followed by the Meisenheimer complex formation between –NO2 groups of TNT and primary amines of the Cysteamine functionalised AuNR (Turn-On) which gives corresponding fluorescent signals in the visible regions. The fluorescence turn-on is immediate, and the limit of detection is as low as 11.88 x 10−9 M. The above-mentioned phenomena were substantiated using the UV–Visible, Photoluminescence, and Time-Correlated Single Photon Counting spectroscopic techniques. The size, morphology, particle interactions, charge, and functionalisations were substantiated through TEM, DLS, Zeta potential, and FTIR techniques. The size variations happened to the AuNR in three different stages are evident from the TEM images. (i) when AuNR (Gold nanorod) is present alone, i.e. LnNp and TNT free system, the average size of AuNR was 15.17 nm (ii) When LnNp (Lanthanide Nanophosphor) was added (attached), i.e. AuNR + LnNp involved state, the average size of AuNR was increased to 23.05 nm (iii) When TNT was introduced to AuNR + LnNp system (Analyte attachment and LnNp detachment happening state) i.e. AuNR + LnNp + TNT involved state, the average size of AuNR was decreased to16.3 nm as it was in its pristine form. The same trend was obtained for the DLS measurements.

Keywords

Lanthanide Nanophosphor Gold nanorod Magneto-Luminescent FRET Turn-on sensor Photonics 
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Notes

Acknowledgments

The authors thank the Head of CSIR-NIIST (Pappanamcode), CESS (Thiruvananthapuram), SAIF-IIT (Madras), SCT-IMST (Poojapura), Departments of Bio-Technology & Bio-Chemistry, University of Kerala, Kariavattom campus, (Thiruvananthapuram) for the sophisticated characterization techniques provided for the work.

Supplementary material

11051_2014_2522_MOESM1_ESM.pptx (529 kb)
Fig. S1. The VSM plot of Gd2O3: Eu@MPA Lanthanide nanophosphor taken at Room Temperature. Fig. S2 The Zeta potential (ξ) distribution curve of Gd2O3: Eu@MPA Lanthanide nanophosphor Fig. S3 The Zeta potential (ξ) distribution curve of AuNR@Cysteamine. Fig. S4 FT-IR spectrum of MPA modified LnNP (Gd2O3: Eu@MPA) Fig. S5 FT-IR spectrum of Cysteamine modified AuNR-626 Fig. S6 The DLS size distribution of individual AuNR @ cystemine system Fig. S7 The DLS size distribution of LnNP @MPA: AuNR @ cystemine system Fig. S8 The DLS size distribution of LnNP @MPA: AuNR @ cystemine + TNT system (PPTX 529 kb)
11051_2014_2522_MOESM2_ESM.doc (39 kb)
Supplementary material 2 (DOC 39 kb)

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Copyright information

© Springer Science+Business Media Dordrecht 2014

Authors and Affiliations

  • G. L. Praveen
    • 1
  • G. M. Lekha
    • 1
  • V. M. Visakh
    • 1
  • L. R. Reshma
    • 1
  • Sony George
    • 1
  1. 1.Department of ChemistryUniversity of KeralaTrivandrumIndia

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