Ultra-sensitive fluorescence spectroscopy of isolated surface-adsorbed molecules using an optical nanofiber

Stiebeiner, Ariane; Rehband, O.; Garcia-Fernandez, R.; Rauschenbeutel, Arno

doi:10.1364/oe.17.021704

Cited by 50 publications

(55 citation statements)

References 24 publications

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“…Isolated PTCDA molecules have already been studied in different liquid solvents [40], in solid SiO 2 matrix [41], on optical nanofibers [42] (sub-monolayer deposition) and with UPS in the gas phase [43,44]. In all these cases there is a strong interaction of the PTCDA with an environment.…”

Section: Introductionmentioning

confidence: 99%

Vibronic line shapes of PTCDA oligomers in helium nanodroplets

Roden¹,

Eisfeld²,

Dvořák³

et al. 2011

The Journal of Chemical Physics

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Oligomers of the organic semiconductor PTCDA are studied by means of helium nanodroplet isolation (HENDI) spectroscopy. In contrast to the monomer absorption spectrum, which exhibits clearly separated, very sharp absorption lines, it is found that the oligomer spectrum consists of three main peaks having an apparent width orders of magnitude larger than the width of the monomer lines. Using a simple theoretical model for the oligomer, in which a Frenkel exciton couples to internal vibrational modes of the monomers, these experimental findings are nicely reproduced. The three peaks present in the oligomer spectrum can already be obtained taking only one effective vibrational mode of the PTCDA molecule into account. The inclusion of more vibrational modes leads to quasi continuous spectra, resembling the broad oligomer spectra.

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Section: Introductionmentioning

confidence: 99%

Vibronic line shapes of PTCDA oligomers in helium nanodroplets

Roden¹,

Eisfeld²,

Dvořák³

et al. 2011

The Journal of Chemical Physics

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“…For essentially plane waves in isotropic media, it has been quantitatively investigated in a number of groundbreaking experiments at the level of single atoms and single photons in high-finesse cavities [1][2][3][4][5][6][7][8]. In order to further enhance the light-matter coupling strength, an increasing number of recent experiments rely on waveguide structures [9][10][11], or high NA objectives [12][13][14]. However, in these situations, the physics changes drastically from the plane wave case because the polarization of the light fields is in general no longer transversal but exhibits a longitudinal component in the direction of propagation.…”

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confidence: 99%

Strong Coupling between Single Atoms and Nontransversal Photons

et al. 2013

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Light is often described as a fully transverse-polarized wave, i.e., with an electric field vector that is orthogonal to the direction of propagation. However, light confined in dielectric structures such as optical waveguides or whispering-gallery-mode microresonators can have a strong longitudinal polarization component. Here, using single 85 Rb atoms strongly coupled to a whispering-gallerymode microresonator, we experimentally and theoretically demonstrate that the presence of this longitudinal polarization fundamentally alters the interaction between light and matter.PACS numbers: 42.50. Pq,42.50.Ct,42.60.Da,42.25.Ja The interaction between light and matter underlies basically every optical process and application. For essentially plane waves in isotropic media, it has been quantitatively investigated in a number of groundbreaking experiments at the level of single atoms and single photons in high-finesse cavities [1][2][3][4][5][6][7][8]. In order to further enhance the light-matter coupling strength, an increasing number of recent experiments rely on waveguide structures [9][10][11], or high NA objectives [12][13][14]. However, in these situations, the physics changes drastically from the plane wave case because the polarization of the light fields is in general no longer transversal but exhibits a longitudinal component in the direction of propagation. This tags the propagation direction of the light by its polarization state and fundamentally renders full destructive interference of two counter-propagating waves impossible. One would thus expect this effect to have striking consequences for the physics of light-matter interaction.Here, we quantitatively investigate this phenomenon in a model system consisting of single atoms that strongly interact with a whispering-gallery-mode (WGM) microresonator [15]. These resonators confine light by continuous total internal reflection and offer the advantage of very long photon lifetimes in conjunction with nearlossless in-and out-coupling of light via tapered fibre couplers [16]. As recently demonstrated in a series of pioneering experiments with toroidal WGM microresonators [17][18][19][20][21][22], single atoms as well as solid state quantum emitters can be strongly coupled to WGMs. Beyond their importance in strong light-matter coupling, WGM microresonators are highly versatile photonic devices which have found applications in a large variety of disciplines. They have enabled, e.g., on-chip detection of single nanoparticels [23] and single viruses [24], the generation of optical frequency combs [25] as well as squeezed and correlated twin-beams and single and pair photons [26,27]. Moreover, WGM microresonators provide a successful experimental platform in the thriving field of cavity optomechanics [28,29].However, thus far, the non-transversal polarization of WGMs has not been taken into account in the description of the quantum mechanical interaction of light and mat-FIG. 1. a) Schematic view of our bottle microresonator interfaced with a tapered fibre cou...

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“…Due to the strong evanescent field at the surface, such TOFs promise coupling efficiencies up to 36% 13,14 and approaching unity when combined with Bragg-grating cavities 15,16 . Until now, evanescent coupling of fluorescence photons to a single guided mode of a TOF has been achieved for a) email: lars.liebermeister@physik.uni-muenchen.de b) email: markusweber@lmu.de various solid state quantum emitters [17][18][19][20] , molecules 21 , and laser-cooled atomic vapors 22 . To bring these emitters into the strong evanescent optical field at the surface of the nano-fiber several non-deterministic deposition techniques like dip-coating 17,18 , picoliter-dispensers 19,20 , and optical surface traps 23 have been applied.…”

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confidence: 99%

Tapered fiber coupling of single photons emitted by a deterministically positioned single nitrogen vacancy center

Liebermeister¹,

Petersen²,

Münchow³

et al. 2014

Appl. Phys. Lett.

122

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A diamond nano-crystal hosting a single nitrogen vacancy (NV) center is optically selected with a confocal scanning microscope and positioned deterministically onto the subwavelength-diameter waist of a tapered optical fiber (TOF) with the help of an atomic force microscope. Based on this nano-manipulation technique we experimentally demonstrate the evanescent coupling of single fluorescence photons emitted by a single NV-center to the guided mode of the TOF. By comparing photon count rates of the fiber-guided and the free-space modes and with the help of numerical FDTD simulations we determine a lower and upper bound for the coupling efficiency of (9.5 ± 0.6)% and (10.4 ± 0.7)%, respectively. Our results are a promising starting point for future integration of single photon sources into photonic quantum networks and applications in quantum information science.PACS numbers: 03.67. 42.50.Ex, 78.67.Bf Efficient collection of single photons radiated by a single solid state quantum emitter -like the nitrogen vacancy (NV) center in diamond 1 -is an important prerequisite for future applications in applied physical and quantum information science, like ultra-sensitive fluorescence spectroscopy and linear optical quantum computation 2-4 . A standard technique for fluorescence collection is confocal microscopy. However, when applied to defect centers in bulk diamond, total internal reflection limits the collection efficiency to few percent. Recently, the collection efficiency of NV-fluorescence has been increased by one order of magnitude by combining confocal microscopy with solid immersion lenses (SILs) 5-7 , respectively photonic nanowires 8 . In the latter system the improvement is based on efficient coupling of NV-fluorescence photons to the strongly confined mode (HE 11 ) 9-11 of diamond nanowires. For defect centers in diamond nano-crystals, tapered optical fibers (TOFs) 12 with a subwavelength diameter waist are a particularly attractive alternative platform. Due to the strong evanescent field at the surface, such TOFs promise coupling efficiencies up to 36%13,14 and approaching unity when combined with Bragg-grating cavities 15,16 . Until now, evanescent coupling of fluorescence photons to a single guided mode of a TOF has been achieved for a) email: lars.liebermeister@physik.uni-muenchen.de b) email: markusweber@lmu.de various solid state quantum emitters 17-20 , molecules 21 , and laser-cooled atomic vapors 22 . To bring these emitters into the strong evanescent optical field at the surface of the nano-fiber several non-deterministic deposition techniques like dip-coating 17,18 , picoliter-dispensers 19,20 , and optical surface traps 23 have been applied. However, for real applications in quantum information science, e. g., the photonic quantum-bus mediated coupling of NVcenters in a lattice 24 , deterministic positioning of single solid state quantum emitters onto the submicron waist of a TOF with nm position control is desirable. In this letter we demonstrate significant steps towards deterministic coup...

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Ultra-sensitive fluorescence spectroscopy of isolated surface-adsorbed molecules using an optical nanofiber

Cited by 50 publications

References 24 publications

Vibronic line shapes of PTCDA oligomers in helium nanodroplets

Vibronic line shapes of PTCDA oligomers in helium nanodroplets

Strong Coupling between Single Atoms and Nontransversal Photons

Tapered fiber coupling of single photons emitted by a deterministically positioned single nitrogen vacancy center

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