Breaking the Diffraction Limit in Absorption Spectroscopy Using Upconverting Nanoparticles

Overview

Journal Nanoscale

Specialty Biotechnology

Date 2021 Jun 30

PMID 34190292

Citations 3

Authors

Sumeet Kumar

Gunaseelan M

Rahul Vaippully

Ayan Banerjee

Basudev Roy

Affiliations

Soon will be listed here.

Abstract

We employ a single optically trapped upconverting nanoparticle (UCNP) of NaYF4:Yb,Er of diameter about 100 nm as a subdiffractive source to perform absorption spectroscopy. The experimentally expected mode volume of 100 nm of the backscatter profile of the nanoparticle matches well with a numerical simulation of the dominant backscattering modes to confirm our assertion of achieving a source dimension considerably lower than the diffraction limit set by the excitation wavelength of 975 nm for the UCNP. We perform absorption spectroscopy of several diverse entities such as the dye Rhodamine B in water, a thin gold film of thickness 30 nm, and crystalline soft oxometalates micro-patterned on a glass substrate using the UCNP as a source. The initial results lead to unambiguous utility of UCNPs as single nanoscopic sources for absorption spectroscopy of ultra-small sample volumes (femtolitres), and lead us to hypothesize a possible Resonance Energy Transfer mechanism between the UCNP and the molecules of the ambient medium, which may even lead to single molecule absorption spectroscopy applications.

Citing Articles

Facets of optically and magnetically induced heating in ferromagnetically doped-NaYF particles.

Chakraborty S, Nalupurackal G, Gunaseelan M, Roy S, Lokesh M, Goswami J J Phys Commun. 2023; 7(6):065008.

PMID: 37398924 PMC: 7614712. DOI: 10.1088/2399-6528/acde43.

Generation of partial roll rotation in a hexagonal NaYF particle by switching between different optical trapping configurations.

Lokesh M, Nalupurackal G, Roy S, Chakraborty S, Goswami J, M G Opt Express. 2022; 30(16):28325-28334.

PMID: 35919192 PMC: 7613164. DOI: 10.1364/OE.462932.

Realization of pitch-rotational torque wrench in two-beam optical tweezers.

Lokesh M, Vaippully R, Bhallamudi V, Prabhakar A, Roy B J Phys Commun. 2021; 5:115016.

PMID: 34869919 PMC: 7612066.

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