Near-field interactions between a subwavelength tip and a small-volume photonic-crystal nanocavity

Lalouat, Loı̈c; Cluzel, Benoît; Velha, Philippe; Picard, E.; Peyrade, D.; Hugonin, Jean‐Paul; Lalanne, Philippe; Hadji, E.; Fornel, Frédérique de

doi:10.1103/physrevb.76.041102

Cited by 64 publications

(74 citation statements)

References 16 publications

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“…The reconstructed field patterns are an approximation of the Bloch modes propagating in the system and moreover, they are not necessarily orthogonal because of quasi-interference. Although the effect of the tip is far from straightforward ( [5,20,21]), we anticipate that the comparison between calculated modes of an optical system and reconstructed modes could lead to methods to deduce the response function of a near-field tip. Next, we demonstrate the power of the reconstruction algorithm by studying the transverse behavior of TE-like mode (A) versus wavevector.…”

Section: Samples and Methodsmentioning

confidence: 99%

Extraction of optical Bloch modes in a photonic-crystal waveguide

Huisman

Ctistis

Stobbe

et al. 2012

Journal of Applied Physics

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We perform phase-sensitive near-field scanning optical microscopy on photonic-crystal waveguides. The observed intricate field patterns are analyzed by spatial Fourier transformations, revealing several guided TE-and TM-like modes. Using the reconstruction algorithm proposed by Ha, et al. (Opt. Lett. 34 (2009)), we decompose the measured two-dimensional field pattern in a superposition of propagating Bloch modes. This opens new possibilities to study specific modes in near-field measurements. We apply the method to study the transverse behavior of a guided TE-like mode, where the mode extends deeper in the surrounding photonic crystal when the band edge is approached.

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Section: Samples and Methodsmentioning

confidence: 99%

Extraction of optical Bloch modes in a photonic-crystal waveguide

Huisman

Ctistis

Stobbe

et al. 2012

Journal of Applied Physics

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“…However, only low-Q cavities have been studied so far and the very first attempts at probing small volume cavities have shown that the near-field probes ͓SNOM probes in Ref. 12 and atomic force microscopy ͑AFM͒ probes in Refs. 13 and 14͔ strongly alter-or even completely disrupt in the case of AFM probes-the light confinement mechanism inside the cavity.…”

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confidence: 99%

“…12 12,13,15 and the classical SNOM collection-scanning mode. [8][9][10][11] The differences between these two imaging methods are discussed in light of the recorded images by comparing them with three-dimensional ͑3D͒ calculations of the cavity mode.…”

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confidence: 99%

“…Consequently, the near-field probe used here operates in a perturbation regime weak enough to avoid a drastic alteration of the light confinement inside the cavity. 12,20 For SNOM measurements, we then develop an experimental setup allowing the simultaneous recording of the near-field maps of the nanocavity in collection-scanning mode [8][9][10][11] and interaction-scanning mode. 12,13,21 The first method is similar to the one used in classical aperture-SNOM measurements, and the probe is used to locally collect the electromagnetic field above the cavity ͓I SNOM ͑x , y , z͒ in Fig.…”

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confidence: 99%

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Subwavelength imaging of light confinement in high-Q/small-V photonic crystal nanocavity

Lalouat¹,

Cluzel²,

Fornel³

et al. 2008

Applied Physics Letters

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International audienceThe optical near field of a high-Q and ultrasmall volume photonic crystal nanocavity is visualized with a subwavelength resolution by using a scanning near-field optical microscope (SNOM) operating at the same time in collection-scanning mode and in interaction-scanning mode. It is shown that the nanocavity resonant mode is selectively visualized by using the SNOM interaction-scanning mode while the whole electromagnetic field surrounding the nanocavity is probed using the SNOM collection-scanning mode. The different optical near-field images are compared in light of a three-dimensional numerical analysis and we demonstrate an unexpected mode coupling at the cavity resonance

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“…This is because, whereas the mode volume of state-of-the-art macroscopic cavities is on the order of 10 5 μm 3 , a photonic crystal nanocavity typically has a mode volume of a cubic wavelength. Because of this small mode volume, a photonic crystal nanocavity can easily be tuned by bringing a nano-object into the near field of the cavity [10][11][12]. For experiments in cavity quantum electrodynamics [13][14][15], a single emitter needs to be brought into the near field of the cavity.…”

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confidence: 99%

Trapping a single atom with a fraction of a photon using a photonic crystal nanocavity

Oosten

Kuipers

2011

Phys. Rev. A

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We consider the interaction between a single rubidium atom and a photonic crystal nanocavity. Because of the ultrasmall mode volume of the nanocavity, an extremely strong coupling regime can be achieved in which the atom can shift the cavity resonance by many cavity linewidths. We show that this shift can be exploited to trap a single atom above the cavity. The atom is trapped by light that is only inside the cavity as a result of the shift of the cavity resonance caused by the proximity of the atom itself. This atom trap requires only a fraction of a photon inside the cavity. Surprisingly, the damping of the cavity plays a pivotal role in this trapping mechanism.

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Near-field interactions between a subwavelength tip and a small-volume photonic-crystal nanocavity

Cited by 64 publications

References 16 publications

Extraction of optical Bloch modes in a photonic-crystal waveguide

Extraction of optical Bloch modes in a photonic-crystal waveguide

Subwavelength imaging of light confinement in high-Q/small-V photonic crystal nanocavity

Trapping a single atom with a fraction of a photon using a photonic crystal nanocavity

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