Adiabatic Tip-Plasmon Focusing for Nano-Raman Spectroscopy

Berweger, Samuel; Atkin, Joanna M.; Olmon, Robert L.; Raschke, Markus B.

doi:10.1021/jz101289z

Cited by 164 publications

(163 citation statements)

References 41 publications

Supporting

Mentioning

159

Contrasting

Unclassified

Order By: Relevance

“…By relying on the diverging index of refraction experienced by propagating SPP's with decreasing cone radius, the mode transformation into a nanoscale excitation at the tip apex remains continuous and impedance matched [7], while 6 the uniform taper surface prevents the otherwise typical scattering and reflection losses at structural discontinuities. Due to the radial symmetry and decreasing SPP group velocity, full nanoconfinement in all spatial dimensions is achieved [21,22,26].In addition, the tips allow for the desired broadband excitation necessary for true femtosecond optical control. As predicted theoretically, the nanofocusing efficiency is maximal in the 800 nm range for a tip cone angle of ∼14 • [23] as used in our experiment with previously demonstrated monochromatic nanofocusing efficiencies of up to 9% [26].…”

mentioning

confidence: 99%

“…Due to the radial symmetry and decreasing SPP group velocity, full nanoconfinement in all spatial dimensions is achieved [21,22,26].…”

mentioning

confidence: 99%

“…This light source with arbitrary waveform control at the nanoscale is of a fundamentally new quality compared to both conventional far-and near-field sources. It allows for the systematic extension of near background-free scanning probe microscopy [22,26,30] to the nanoscale implementation of many forms of nonlinear and ultrafast spectroscopies for spatio-temporal imaging [31].…”

mentioning

confidence: 99%

See 2 more Smart Citations

Femtosecond Nanofocusing with Full Optical Waveform Control

et al. 2011

Self Cite

View full text Add to dashboard Cite

The spatial confinement and temporal control of an optical excitation on nanometer length scales and femtosecond time scales has been a long-standing challenge in optics. It would provide spectroscopic access to the elementary optical excitations in matter on their natural length and time scales [1] and enable applications from ultrafast nano-opto-electronics to single molecule quantum coherent control [2]. Previous approaches have largely focused on using surface plasmon polariton (SPP) resonant nanostructures [3] or SPP waveguides [4, 5] to generate nanometer localized excitations. However, these implementations generally suffer from mode mismatch [6] between the far-field propagating light and the near-field confinement. In addition, the spatial localization in itself may depend on the spectral phase and amplitude of the driving laser pulse thus limiting the degrees of freedom available to independently control the nano-optical waveform. Here we utilize femtosecond broadband SPP coupling, by laterally chirped fan gratings, onto the shaft of a monolithic noble metal tip, leading to adiabatic SPP compression and localization at the tip apex [7, 8]. In combination with spectral pulse shaping [9, 10] with feedback on the intrinsic nonlinear response of the tip apex, we demonstrate the continuous micro-to nano-scale self-similar mode matched transformation of the propagating femtosecond SPP field into a 20 nm spatially and 16 fs temporally confined light pulse at the tip apex.Furthermore, with the essentially wavelength and phase independent 3D focusing mechanism we show the generation of arbitrary optical waveforms nanofocused at the tip. This unique femtosecond nano-torch with high nano-scale power delivery in free space and full spectral and temporal control opens the door for the extension of the powerful nonlinear and ultrafast vibrational and electronic spectroscopies to the 2 nanoscale [11, 12].In order to achieve the goal of an efficient nanometer confined femtosecond light source with independent spatial localization and temporal control of the optical field, and which can freely be manipulated in 3D, the use of the unique properties of surface plasmon polaritons (SPP's) has long been discussed as a potential solution. It is well established that the strong surface field localization and size and shape dependent resonances of SPP's as electromagnetic surface waves associated with collective charge density oscillations at noble metal-dielectric interfaces allow for sub-wavelength spatial control of even broadband optical fields [13]. Elegant solutions to overcome the SPP diffraction limit [14] and achieve nano-focusing based on interference of localized SPP modes exist in the form of specially arranged cascaded, percolated, or self-similar chains of metal nanostructures as optical antennas [3,15,16]. However, the achievable optical waveforms at the nano-focus are often constrained by the phase relationship between the spectral modes already necessary to achieve the 3D nano-focusing [5]. This limits ...

show abstract

mentioning

confidence: 99%

“…Due to the radial symmetry and decreasing SPP group velocity, full nanoconfinement in all spatial dimensions is achieved [21,22,26].…”

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Femtosecond Nanofocusing with Full Optical Waveform Control

et al. 2011

Self Cite

View full text Add to dashboard Cite

show abstract

“…As previously shown, SPP nanofocusing can generate a nanoconfined excitation with 10's of nm spatial confinement where nanofocusing efficiencies as high as 9% enable efficient background-free imaging and spectroscopy [8,9]. Under sufficiently high illumination conditions SHG is generated locally at the tip apex that is used through a MIIPS algorithm to produce transform-limited pulses.…”

Section: Resultsmentioning

confidence: 97%

Femtosecond optical control on the nanoscale

Berweger

Atkin

et al. 2013

EPJ Web of Conferences

Self Cite

View full text Add to dashboard Cite

show abstract

“…Indeed, lower background intensities have been observed with remote excitation relative to direct excitation, demonstrated by both our group and other researchers. [19][20][21][22][23] A notable example of this is given by Berweger et al, who created a grating structure as a light coupling point on a chemically etched gold tip. 22,23) As here, this resulted in a vertical separation of the excitation and detection spots, and led to a lower background intensity than when the laser was focused to the tip apex.…”

Section: Tersmentioning

confidence: 99%

Remote excitation-tip-enhanced Raman scattering microscopy using silver nanowire

Fujita¹,

Walke²,

Feyter³

et al. 2016

Jpn. J. Appl. Phys.

View full text Add to dashboard Cite

Tip-enhanced Raman scattering (TERS) microscopy is a promising technique for use in surface analysis, allowing both topographic and spectroscopic information to be obtained simultaneously at a scale below 10 nm. One proposed method to further improve spatial resolution is the use of propagating surface plasmons as an excitation light source (i.e., remote excitation). However, this requires a specialized tip that can only be fabricated via expensive procedures, such as electron-beam lithography. Here, we propose a new method for fabricating silver nanowire-based tips that are suitable for remote excitation-TERS, removing the need for such techniques. A silver nanowire was fixed onto a tungsten-tip using a micromanipulator, before gold nanoparticles were attached in a site-specific manner using AC-dielectrophoresis. All the processes were completed using an optical microscope in the ambient. The background intensities in TERS spectra were suppressed with remote excitation relative to the conventional excitation configuration, indicating an increase in TERS sensitivity.

show abstract

Adiabatic Tip-Plasmon Focusing for Nano-Raman Spectroscopy

Cited by 164 publications

References 41 publications

Femtosecond Nanofocusing with Full Optical Waveform Control

Femtosecond Nanofocusing with Full Optical Waveform Control

Femtosecond optical control on the nanoscale

Remote excitation-tip-enhanced Raman scattering microscopy using silver nanowire

Contact Info

Product

Resources

About