Direct phase mapping of the light scattered by single plasmonic nanoparticles

Hauler, Otto; Wackenhut, Frank; Jakob, Lukas A.; Stuhl, Alexander; Laible, Florian; Fleischer, Monika; Meixner, Alfred J.; Braun, Kai

doi:10.1039/c9nr10358a

Cited by 7 publications

(16 citation statements)

References 26 publications

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“…Τhe energy of this band is at 15523.8 cm −1 (

ν

em =

ν

0 ‐

ν

Rs , where

ν

0 is the wavenumber of the incident laser light and

ν

Rs the wavenumber of the band which appears in the Stokes side of Raman spectrum) that corresponds to 644.2 nm. Emission bands with similar energy have been observed when exciting gold nanostructures with the excitation line 632.8 nm that we also used [18] . As it has been reported before, [19] laser induced dissociation/reduction of the colored Au 2 Cl 6 vapors by the absorbed laser line resulted to solid deposits (Au and/or AuCl) that obscured the Raman spectra [19] …”

Section: Figuresupporting

confidence: 62%

“…Emission bands with similar energy have been observed when exciting gold nanostructures with the excitation line 632.8 nm that we also used. [18] As it has been reported before, [19] laser induced dissociation/reduction of the colored Au 2 Cl 6 vapors by the absorbed laser line resulted to solid deposits (Au and/or AuCl) that obscured the Raman spectra. [19] In conclusion, in the present study, we have studied the generation and growth of gold-based chemical gardens.…”

mentioning

confidence: 78%

“…While recording micro‐Raman spectra the laser power was kept low (0.3 mW on the sample) and the accumulation time short (2 min) in order to avoid spectral changes due to heat‐induced effects, observed in Figure 4 (spectra (b)), where a new strong peak appears at 279 cm −1 . A possible explanation is that this intense band can be attributed to an emission/scattering, probably from gold nanostructures [18] formed due to laser induced dissociation of the Au(III) compounds after prolonged exposure of the sample to laser radiation. Τhe energy of this band is at 15523.8 cm −1 (

ν

em =

ν

0 ‐

ν

Rs , where

ν

0 is the wavenumber of the incident laser light and

ν

Rs the wavenumber of the band which appears in the Stokes side of Raman spectrum) that corresponds to 644.2 nm.…”

Section: Figurementioning

confidence: 99%

See 2 more Smart Citations

The Generation and Study of a Gold‐Based Chemobrionic Plant‐Like Structure

2020

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The generation of chemical gardens based on tetrachloroauric acid and silicate is presented. The structures were studied with SEM, XRD and micro‐Raman spectroscopy and a new mechanism that participates in their development was revealed. Specifically, the structures were decorated with metallic Au that is derived during the process of plant‐like growth. Probably, the instability of gold salts and hydroxides on silica templates accounts for their reduction to metallic Au.

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“…Τhe energy of this band is at 15523.8 cm −1 (

ν

em =

ν

0 ‐

ν

Rs , where

ν

0 is the wavenumber of the incident laser light and

ν

Section: Figuresupporting

confidence: 62%

mentioning

confidence: 78%

ν

em =

ν

0 ‐

ν

Rs , where

ν

0 is the wavenumber of the incident laser light and

ν

Rs the wavenumber of the band which appears in the Stokes side of Raman spectrum) that corresponds to 644.2 nm.…”

Section: Figurementioning

confidence: 99%

See 1 more Smart Citation

The Generation and Study of a Gold‐Based Chemobrionic Plant‐Like Structure

2020

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“…In most cases, white-light scattering is used to characterize the plasmonic properties of nanostructures. Scattering-based methods, such as defocused dark-field imaging, back focal plane imaging, interferometric scattering microscopy, , and direct phase mapping are utilized to distinguish the geometrical properties of nanoparticles. However, scattering methods suffer from a scattering background that originates from impurities and interfaces, which is especially problematic in biological applications.…”

Section: Introductionmentioning

confidence: 99%

Revealing the Three-Dimensional Orientation and Interplay between Plasmons and Interband Transitions for Single Gold Bipyramids by Photoluminescence Excitation Pattern Imaging

Liu

Wackenhut

et al. 2021

J. Phys. Chem. C

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Gold bipyramids (AuBPs) attract significant attention due to the large enhancement of the electric field around their sharp tips and well-defined tunability of their plasmon resonances. Excitation patterns of single AuBPs are recorded using raster-scanning confocal microscopy combined with radially and azimuthally polarized laser beams. Photoluminescence spectra (PL) and excitation patterns of the same AuBPs are acquired with three different excitation wavelengths. The isotropic excitation patterns suggest that the AuBPs are mainly excited by interband transitions with 488/530 nm radiation, while excitation patterns created with a 633 nm laser exhibit a double-lobed shape that indicates a single-dipole excitation process associated with the longitudinal plasmon resonance mode. We are able to determine the three-dimensional orientation of single AuBPs nonperturbatively by comparing experimental patterns with theoretical simulations. The asymmetric patterns show that the AuBPs are lying on the substrate with an out-of-plane tilt angle of around 10−15°.

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“…Since these pioneering works, technology has advanced rapidly, and different phase-detecting techniques are of crucial importance across many scientific fields. In nanoscale physics, the phase of a nanoparticle (NP) accesses its nanoscale response − and is a crucial parameter for tailoring complex photonic structures such as metasurfaces which manipulate the amplitude, direction, and polarization of light at nano- to microscales. , In the biomedical sciences, phase-based measurements are often key enablers for ultrasensitive measurements such as protein-binding to plasmonic structures, − and the emerging field of quantitative phase imaging is expected to dramatically contribute to future diagnostics. , …”

mentioning

confidence: 99%

One-Shot Phase Image Distinction of Plasmonic and Dielectric Nanoparticles

2021

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Nanoscale phase-control is one of the most powerful approaches to specifically tailor electrical fields in modern nanophotonics. Especially the precise sub-wavelength assembly of many individual nano-building-blocks has given rise to exciting new materials as diverse as metamaterials, for miniaturizing optics, or 3D assembled plasmonic structures for biosensing applications. Despite its fundamental importance, the phase-response of individual nanostructures is experimentally extremely challenging to visualize. Here, we address this shortcoming and measure the quantitative scattering phase of different nanomaterials such as gold nanorods and spheres as well as dielectric nanoparticles. Beyond reporting spectrally resolved responses, with phase-changes close to π when passing the particles' plasmon resonance, we devise a simple method for distinguishing different plasmonic and dielectric particles purely based on their phase behavior. Finally, we integrate this novel approach in a single-shot two-color scheme, capable of directly identifying different types of nanoparticles on one sample, from a single widefield image.Phase, an elusive quantity in day-to-day life, is one of the most crucial parameters in physics and the lifesciences. Historically, measurements based on phase-contrast have proven to be extremely powerful and highly sensitive to tiny changes in the morphology of structures 1 even if the underlying absolute phasevalue remained unobserved. Since these pioneering works, technology has advanced rapidly and different phase-detecting techniques are of crucial importance across many scientific fields. In nanoscale physics, the phase of a nanoparticle (NP) accesses its nanoscale response 2-5 and is a crucial parameter for tailoring complex photonic structures such as metasurfaces which manipulate the amplitude, direction and polarization of light at nano-to micro-scales 6,7 . In the biomedical sciences, phase-based measurements are often key enablers for ultrasensitive measurements 8 such as protein-binding to plasmonic structures [9][10][11] and the emerging field of quantitative phase imaging is expected to dramatically contribute to future diagnostics 12,13 . However, even though macro-scale phase measurements are relatively easy to implement, determining the absolute scattering phase of individual nano-objects is far from trivial as one has to consider the phase of the observation wave and account for the sub-diffraction limited nature of the particle. A versatile experimental approach to directly and reproducibly determine the absolute phase of such objects would both advance the observation-based development of nanophotonic materials and allow implementing novel imaging methodologies that exploit absolute phase measurements as a robust contrast mechanism for distinguishing and identifying different materials in a complex environment.

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Direct phase mapping of the light scattered by single plasmonic nanoparticles

Cited by 7 publications

References 26 publications

The Generation and Study of a Gold‐Based Chemobrionic Plant‐Like Structure

The Generation and Study of a Gold‐Based Chemobrionic Plant‐Like Structure

Revealing the Three-Dimensional Orientation and Interplay between Plasmons and Interband Transitions for Single Gold Bipyramids by Photoluminescence Excitation Pattern Imaging

One-Shot Phase Image Distinction of Plasmonic and Dielectric Nanoparticles

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