Comparison of Free-Space and Waveguide-Based SERS Platforms.
Raman spectroscopy
SERS
gold nanodomes
nanoplasmonic slot waveguide
peptide detection
photonic integrated circuit
waveguide-based SERS
Journal
Nanomaterials (Basel, Switzerland)
ISSN: 2079-4991
Titre abrégé: Nanomaterials (Basel)
Pays: Switzerland
ID NLM: 101610216
Informations de publication
Date de publication:
01 Oct 2019
01 Oct 2019
Historique:
received:
30
08
2019
revised:
24
09
2019
accepted:
28
09
2019
entrez:
5
10
2019
pubmed:
5
10
2019
medline:
5
10
2019
Statut:
epublish
Résumé
Surface-Enhanced Raman Spectroscopy (SERS) allows for the highly specific detection of molecules by enhancing the inherently weak Raman signals near the surface of plasmonic nanostructures. A variety of plasmonic nanostructures have been developed for SERS signal excitation and collection in a conventional free-space microscope, among which the gold nanodomes offer one of the highest SERS enhancements. Nanophotonic waveguides have recently emerged as an alternative to the conventional Raman microscope as they can be used to efficiently excite and collect Raman signals. Integration of plasmonic structures on nanophotonic waveguides enables reproducible waveguide-based excitation and collection of SERS spectra, such as in nanoplasmonic slot waveguides. In this paper, we compare the SERS performance of gold nanodomes, in which the signal is excited and collected in free space, and waveguide-based nanoplasmonic slot waveguide. We evaluate the SERS signal enhancement and the SERS background of the different SERS platforms using a monolayer of nitrothiophenol. We show that the nanoplasmonic slot waveguide approaches the gold nanodomes in terms of the signal-to-background ratio. We additionally demonstrate the first-time detection of a peptide monolayer on a waveguide-based SERS platform, paving the way towards the SERS monitoring of biologically relevant molecules on an integrated lab-on-a-chip platform.
Identifiants
pubmed: 31581547
pii: nano9101401
doi: 10.3390/nano9101401
pmc: PMC6835592
pii:
doi:
Types de publication
Journal Article
Langues
eng
Références
Faraday Discuss. 2017 Dec 4;205:345-361
pubmed: 28920115
Angew Chem Int Ed Engl. 2014 May 5;53(19):4756-95
pubmed: 24711218
Nanoscale. 2016 Feb 14;8(6):3226-31
pubmed: 26791593
Nano Lett. 2013;13(11):5449-53
pubmed: 24111580
Nano Lett. 2012 Mar 14;12(3):1660-7
pubmed: 22339688
Nat Mater. 2008 Jun;7(6):442-53
pubmed: 18497851
Opt Express. 2013 Jul 15;21(14):16561-9
pubmed: 23938507
Phys Chem Chem Phys. 2014 Apr 14;16(14):6544-9
pubmed: 24584480
Opt Express. 2017 May 29;25(11):12926-12934
pubmed: 28786644
Opt Lett. 2014 Jul 1;39(13):4025-8
pubmed: 24978798
Nanomaterials (Basel). 2017 Jun 08;7(6):
pubmed: 28594385
Opt Express. 2016 Sep 19;24(19):21244-55
pubmed: 27661868
J Am Chem Soc. 2013 Nov 20;135(46):17387-92
pubmed: 24160263
Annu Rev Phys Chem. 2007;58:267-97
pubmed: 17067281
Opt Express. 2015 Mar 9;23(5):6793-802
pubmed: 25836898
Opt Express. 2015 Feb 9;23(3):3088-101
pubmed: 25836168
Nano Lett. 2013 Feb 13;13(2):559-63
pubmed: 23339834
Nano Lett. 2015 Apr 8;15(4):2600-4
pubmed: 25734469
Opt Express. 2014 Dec 15;22(25):30528-37
pubmed: 25606999
Chem Rev. 2011 Jun 8;111(6):3913-61
pubmed: 21542636
Opt Express. 2019 Aug 5;27(16):23067-23079
pubmed: 31510589
Nat Rev Drug Discov. 2010 Sep;9(9):690-701
pubmed: 20811381
Nano Lett. 2013 Feb 13;13(2):497-503
pubmed: 23273336
Anal Chem. 2005 Jul 1;77(13):4013-9
pubmed: 15987105
ACS Nano. 2010 May 25;4(5):2804-10
pubmed: 20429521
Nanoscale. 2014 Nov 7;6(21):12391-6
pubmed: 25231127
Science. 2002 Oct 11;298(5592):399-402
pubmed: 12376698
Chem Rev. 2011 Jun 8;111(6):3888-912
pubmed: 21434605
Analyst. 2015 Dec 21;140(24):8080-7
pubmed: 26438890
Opt Express. 2018 Sep 17;26(19):24614-24620
pubmed: 30469574