Efficient unidirectional nanoslit couplers for surface plasmons

López-Tejeira, F.; Rodrigo, Sergio G.; Martín‐Moreno, Luis; García‐Vidal, F. J.; Devaux, Éloïse; Ebbesen, Thomas W.; Krenn, Joachim R.; Radko, Ilya P.; Bozhevolnyi, Sergey I.; González, María Ujué; Weeber, Jean Claude; Dereux, Alain

doi:10.1038/nphys584

Cited by 472 publications

(351 citation statements)

References 26 publications

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“…Interference between SPP waves was reported in pure metal systems [57,58,65,66]. To confirm that what shown in Fig.1b is due to interference of SPPs with the incident wave, we examine a series of d values, and plot the absorption in the exposed SLG within the first 100nm from the contact edge.…”

supporting

confidence: 54%

“…One way to overcome this is by diffraction, whereby the continuity of the component of momentum parallel to the surface is broken and incident light can scatter into SPPs [45]. This can be achieved by a nano-slit [57,58], a diffracting element [59,60], or a grating coupler [59,61]. In the latter case, in particular, a periodic array of metal ridges and grooves delivers the additional momentum according to [45]:…”

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confidence: 99%

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Surface Plasmon Polariton Graphene Photodetectors

et al. 2015

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The combination of plasmonic nanoparticles and graphene enhances the responsivity and spectral selectivity of graphene-based photodetectors. However, the small area of the metal-graphene junction, where the induced electron-hole pairs separate, limits the photoactive region to sub-micron length scales. Here, we couple graphene with a plasmonic grating and exploit the resulting surface plasmon polaritons to deliver the collected photons to the junction region of a metal-graphenemetal photodetector. This results into a 400% enhancement of responsivity and a 1000% increase in photoactive length, combined with tunable spectral selectivity. The interference between surface plasmon polaritons and the incident wave introduces new functionalities, such as light flux attraction or repulsion from the contact edges, enabling the tailored design of the photodetector's spectral response. This architecture can also be used for surface plasmon bio-sensing with direct-electricreadout, eliminating the need of complicated optics.Graphene-based photodetectors (PDs) [1,2] have been reported with ultra-fast operating speeds (up to 262GHz from the measured intrinsic response time of graphene carriers [3]) and broadband operation from the visible and infrared [3][4][5][6][7][8][9][10][11][12][13][14][15][16] up to the THz [17][18][19]. The simplest graphene-based photodetection scheme relies on the metal-graphene-metal (MGM) architecture [5,7,8,11,[20][21][22], where the photoresponse is due to a combination of photo-thermoelectric and photovoltaic effects [5,7,8,11,[20][21][22]. For both mechanisms, the presence of a junction is required to spatially separate excited electronhole (e-h) pairs [5,7,8,11,[20][21][22]. At the metal-graphene junction, a work-function difference causes charge transfer and a shift of the graphene Fermi level underneath the contact [4,5,7,23], compared to that of graphene away from the contact [4,5,7,23], resulting into a build-up of an internal electric field (photovoltaic mechanism) [5,7,24,25] and into a difference of Seebeck coefficients (photo-thermoelectric mechanism) [11,21,26]. An alternative way to create a junction is to use a set of gate electrodes to electrostatically dope graphene [8,11].

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confidence: 54%

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confidence: 99%

Surface Plasmon Polariton Graphene Photodetectors

et al. 2015

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“…For the present device, the extinction ratio defined for δX = 0 is measured to be E R = 47 (η c − = 1.1% and η c + = 52%). The two figures-of-merit are remarkably high with respect to previous results [1][2][6][7][8][9][10]13,14]. In addition, they are achieved for normal incidence; this is really convenient in most applications.…”

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confidence: 62%

Compact Antenna for Efficient and Unidirectional Launching and Decoupling of Surface Plasmons

et al. 2011

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Keywords : surface plasmon polariton, unidirectional launcher and decoupler, plasmonic nanoantenna, diffraction gratings. ABSTRACT :Controlling the launching efficiencies and the directionality of surface plasmon polaritons (SPPs) and their decoupling to freely propagating light is a major goal for the development of plasmonic devices and systems.Here, we report on the design and experimental observation of a highly efficient unidirectional surface plasmon launcher composed of eleven subwavelength grooves, each with a distinct depth and width. Our observations show that, under normal illumination by a focused Gaussian beam, unidirectional SPP launching with an efficiency of at least 52% is achieved experimentally with a compact device of total length smaller than 8 µm. Reciprocally, we report that the same device can efficiently convert SPPs into a highly directive light beam emanating perpendicularly to the sample. 2 Introduction. As the demand for increasing speed and bandwidth of information processing rises, plasmonic

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“…The fan-shaped gratings developed for this work enable a high coupling bandwidth with FWHM of up to ∼ 100 nm (see supplementary 9 material). Improvements in the form of grating structures with optimized groove depth and holographic geometries, chirped gratings including Bragg reflectors [27], broadband coupling via fabricated micro-prism onto the tip shaft [28], spatial pulse shaping in the farfield excitation focus [29], and tip fabrication with reduced surface roughness could further improve the tip performance for nanofocus optical waveform control. Without the need for resonance behavior in order for spatial localization to occur, the process can be extended to a wide range of wavelengths, limited in principle only by material damping at short wavelengths, and taper angle and reduced spatial field confinement at long wavelengths.…”

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confidence: 99%

Femtosecond Nanofocusing with Full Optical Waveform Control

et al. 2011

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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 ...

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Efficient unidirectional nanoslit couplers for surface plasmons

Cited by 472 publications

References 26 publications

Surface Plasmon Polariton Graphene Photodetectors

Surface Plasmon Polariton Graphene Photodetectors

Compact Antenna for Efficient and Unidirectional Launching and Decoupling of Surface Plasmons

Femtosecond Nanofocusing with Full Optical Waveform Control

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