Plasmonic Tip Based on Excitation of Radially Polarized Conical Surface Plasmon Polariton for Detecting Longitudinal and Transversal Fields

Tugchin, Bayarjargal N.; Janunts, Norik; Klein, Angela E.; Steinert, Michael; Fasold, Stefan; Diziain, Séverine; Sison, Miguel; Kley, Ernst‐Bernhard; Tünnermann, Andreas; Pertsch, Thomas

doi:10.1021/acsphotonics.5b00339

Cited by 49 publications

(23 citation statements)

References 49 publications

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“…The eigenvalue equation of HE mn modes for cylindrical metal waveguides is presented. During propagation on the metal tip, the grating-coupled SPPs can be gradually coupled to HE 31 , HE 21 , HE 11 and TM 01 modes, and these modes are sequentially cut off except TM 01 . The TM 01 mode further propagates with drastically increasing effective mode index and thus is converted to LSPs at the tip apex, which is responsible for plasmonic nanofocusing.…”

Section: Discussionmentioning

confidence: 99%

“…4(c). At the same time, the n eff of grating-coupled SPPs is gradually close to that of the HE 21 mode, so part of them is further coupled to the HE 21 mode, as shown in Fig. 4(d), and the HE 21 mode can propagate along the interface of the tip.…”

Section: Hementioning

confidence: 94%

“…The key to achieving plasmonic nanofocusing is the design of metal nanostructures with excellent localized surface plasmon resonance (LSPR) effect, such as wedges 16 , tetrahedrons 17 , grooves 18 , nanoparticles 19 , etc. Besides, it is noteworthy that noble metallic tips can combine electric field enhancement and spatial confinement characteristics to generate nano-confined light source 20,21 . Conical metal tips have been commonly adopted for TERS in the configuration of scanning probe microscopy 22 .…”

Section: Introductionmentioning

confidence: 99%

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Mode evolution and nanofocusing of grating-coupled surface plasmon polaritons on metallic tip

Lu¹,

Zhang²,

Huang³

et al. 2018

Opto-Electronic Advances

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We present a detailed analysis on mode evolution of grating-coupled surface plasmonic polaritons (SPPs) on a conical metal tip based on the guided-wave theory. The eigenvalue equations for SPPs modes are discussed, revealing that cylindrical metal waveguides only support TM 01 and HE m1 surface modes. During propagation on the metal tip, the grating-coupled SPPs are converted to HE 31 , HE 21 , HE 11 and TM 01 successively, and these modes are sequentially cut off except TM 01 . The TM 01 mode further propagates with drastically increasing effective mode index and is converted to localized surface plasmons (LSPs) at the tip apex, which is responsible for plasmonic nanofocusing. The gap-mode plasmons can be excited with the focusing TM 01 mode by approaching a metal substrate to the tip apex, resulting in further enhanced electric field and reduced size of the plasmonic focus.

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Section: Discussionmentioning

confidence: 99%

Section: Hementioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

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Mode evolution and nanofocusing of grating-coupled surface plasmon polaritons on metallic tip

Lu¹,

Zhang²,

Huang³

et al. 2018

Opto-Electronic Advances

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“…an SPP mode). Metal‐coated dielectric tips have also been used to excite SPP at the metal/dielectric interface with relatively low excitation efficiency (∼ 0.3%) . Such excitation efficiency depends on several parameters such as the shape of the tip, the distance of the tip from the interface and the refractive index of the tip, as well as the medium surrounding it.…”

Section: Introductionmentioning

confidence: 99%

Highly Efficient Excitation of Surface Plasmons Using a Si Gable Tip

Dewanjee

Alam

Aitchison

et al. 2017

Laser & Photonics Reviews

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Fabrication method: Figure S1 shows the steps for fabricating the gabled Si tip SPP excitation device. To fabricate the sample, we first obtained a <100> Si wafer and grew 300 nm of SiO2 by thermal oxidation (18 mins in the Bruce technologies oxidation furnace at the Toronto Nano-fabrication Center-TNFC). Then we cleaved a small piece of sample from the oxidized Si wafer. As the next step, we made patterns of 500 nm wide lines and 200 m square pads of ma-N 2400 negative resist on top of the oxidized Si sample using Vistec E-beam lithography unit. Next, we etched the oxide layer using deep reactive ion etching using an Oxford Instruments PlasmaPro Estrelas100 DRIE System unit at the TNFC facilities. After that, we wet-etched the oxide masked Si sample in 45% KOH solution for 7 mins at 80 0 C temperature to create the gabled Si tip structures. The height of the gable tip after the wet etch was measured to be 6 m. Next, we deposited a thick (more than 6 m) PECVD oxide on top of the Sample containing the Si tip, using an Oxford Instruments PlasmaLab System 100 PECVD unit. Then we planarized the top surface of the deposited PECVD oxide using chemical mechanical polishing (CMP). The CMP of the top surface was carried out until the top oxide thickness was reduced to the approximate height of the tip of the Si chimney tip. Further CMP was not carried out to avoid destruction of the Si tip. We also polished the bottom surface of the sample (rough Si) for reducing the defused reflection while coupling light from the bottom. As the next step, we patterned negative resist (ma-N 2400) on the oxide surface for metal deposition and grating fabrication by lift off using the same electron beam lithographic system at TNFC. We used the 200 m square Si marker pads for alignment of the resist patterns for proper positioning of the grating. Then we deposited gold on top of the patterned resist using a Datacomp Electronics TES12D Thermal Evaporator and carried out lift off to fabricate the grating. In the sample layout, hence in the fabricated sample as well the 1 st grating was 10 microns away from the tip of the Si chimney. We fabricated several other gratings at varying distances from the Si tip to monitor the decay of the excited surface plasmon polariton as mentioned in the manuscript. Figure S2 shows the layout of the fabricated sample with the little opening for

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“…The sub-wavelength apertures act as plasmonic waveguides, and the concept of EOT can be applied to a NPDS to enhance the near-field efficiency on a nano-tip array. With near-field enhancements in metallic nano-tips, which have been investigated by various theoretical and experimental studies [14]- [16], localized SPs can secure field enhancement on the nano-tip apex and improve the electron yield of SP-enhanced NPDS. This effect can also be applied to field emitter arrays (FEAs) that can demonstrate an order-ofmagnitude enhancement in brightness with low emittance characteristics [17]- [20].…”

Section: Introductionmentioning

confidence: 99%

Optimization of a Plasmon Enhanced Field Emitter Array Using a Nano-Tip-Based Plasmonic Double-Gate Structure

Lee

Choi

Song

et al. 2016

J. Lightwave Technol.

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A nano-tip-based plasmonic double-gate structure (NPDS) excited by the surface plasmon polariton (SPP) resonance of the gate electrode has recently been proposed to achieve the specifications of the UV laser-induced copper cathode. The function of the NPDS is to generate a high bunch charge via nearinfrared laser-induced field emission without increasing the cathode size. In this study, we report detailed numerical studies of the proposed NPDS to elucidate the physical mechanism of SPP propagation and light-tip coupling via internal SPP resonance. The simulation results show the relationship between the internal SPP resonance and the tip-light coupling in the NPDS, and the feasibility to achieve significant field emission enhancements with the NPDS. Understanding the internal SPP field in the plasmonic double-gate structure and the light field-tip coupling process in the NPDS is of practical importance in designing field emitter devices and could become an important factor in future high-brightness free-electron laser cathodes and high-sensitivity optical biosensors. Index Terms-Surface plasmons (SPs), Nano plasmonics, Nano structure, Free-electron laser cathodeTae Young Kang is with the

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Plasmonic Tip Based on Excitation of Radially Polarized Conical Surface Plasmon Polariton for Detecting Longitudinal and Transversal Fields

Cited by 49 publications

References 49 publications

Mode evolution and nanofocusing of grating-coupled surface plasmon polaritons on metallic tip

Mode evolution and nanofocusing of grating-coupled surface plasmon polaritons on metallic tip

Highly Efficient Excitation of Surface Plasmons Using a Si Gable Tip

Optimization of a Plasmon Enhanced Field Emitter Array Using a Nano-Tip-Based Plasmonic Double-Gate Structure

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