Diffraction Theory

Bouwkamp, C.J.

doi:10.1088/0034-4885/17/1/302

Cited by 750 publications

(342 citation statements)

References 335 publications

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“…This is qualitatively different from the Bethe-Bouwkamp model [51,52] which predicts an electric dipole along the axis normal to the aperture plane. This difference is justified on a symmetry ground due to the conical nature of the NSOM metal coating [45,46] which contrasts with the planar geometry used in the work of Bethe and Bouwkamp.…”

Section: The Aperture Nsom Tipcontrasting

confidence: 87%

“…However, there was to our knowledge no use of such a model for describing the NSOM tip emission prior to our own work. Additionally, it should be observed that in complete analogy with the old work by Stratton and Chu (reviewed by Bouwkamp [52]) we can also include in the present description a fictitious density of "magnetic charge" γ and magnetic current K along the rim in order to introduce a net magnetic dipole in the formalism. The formulas for the dipole and fields generated by such magnetic distributions are obtained by analogy with the electric ones (i.e., Eqs.…”

Section: The Aperture Nsom Tipmentioning

confidence: 89%

“…Therefore, another approach must be developed. Historically the first model used for describing an aperture near-field probe is the one given by Rayleigh, Bethe, and Bouwkamp for the transmission by a subwavelength circular aperture in a infinitely thin and perfectly conducting flat screen [51,52]. However, because of important differences between the geometry considered for the aperture-NSOM tip on the one hand and the ideal flat and thin metal screen of the "Bethe" model on the other hand [45,46] we developed some time ago a different approach [7,49], which takes into account the conical geometry of the optical tip and also the various field symmetries.…”

Section: The Aperture Nsom Tipmentioning

confidence: 99%

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Near-field microscopy with a single-photon point-like emitter: Resolution versus the aperture tip?

Drezet¹,

Cuche²,

Huant³

2011

Optics Communications

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We discuss theoretically the concept of spatial resolution in near-field scanning optical microscopy (NSOM) in light of a recent work [Opt. Express 17 (2009) 19969] which reported on the achievement of active tips made of a single ultrasmall fluorescent nanodiamond grafted onto the apex of a substrate tip and on their validation in NSOM imaging. Since fluorescent nanodiamonds tend to decrease steadily in size, we assimilate a nanodiamond-based tip to a point-like single photon source and compare its ultimate resolution with that offered by standard metal-coated aperture NSOM tips. We demonstrate both classically and quantum mechanically that NSOM based on a point-like tip has a resolving power that is only limited by the scan height over the imaged system whereas the aperture-tip resolution depends critically on both the scan height and aperture diameter. This is a consequence of the complex distribution of the electromagnetic field around the aperture that tends to artificially duplicate the imaged objects. We show that the point-like tip does not suffer from this "squint" and that it rapidly approaches its ultimate resolution in the near-field as soon its scan height falls below the distance between the two nano-objects to be resolved.

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Section: The Aperture Nsom Tipcontrasting

confidence: 87%

Section: The Aperture Nsom Tipmentioning

confidence: 89%

Section: The Aperture Nsom Tipmentioning

confidence: 99%

See 1 more Smart Citation

Near-field microscopy with a single-photon point-like emitter: Resolution versus the aperture tip?

Drezet¹,

Cuche²,

Huant³

2011

Optics Communications

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“…It does not, however, predict several key aspects of coupled wave phenomena. For high frequencyproblems, or equivalently, the situation with large crack size in comparison with wavelength, the KirchhofF approximation [12,13] is applicable if the incident angle is in a restricted range. The basic assumptions involved in the approximation are that the incident field reflects at each point on the defect as though the defect were an infinite plane and the wavefield is zero on the dark side of the crack.…”

Section: Forward Problem and Model Reviewmentioning

confidence: 99%

Finite element study of ultrasonic imaging

1996

NDT & E International

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“…Unfortunately as was shown by Bethe [1] and Bouwkamp [2] the efficiency of such transport is low in the case of subwavelength holes. A remarkable discovery about the transmission of light through a subwavelength hole in a metal screen of a finite thickness and a finite conductivity that has been made by Ebbesen et al [3] has shown that the standard theory of diffraction by small holes is invalid, and, in this case, the transmission of light through the subwavelength hole can be strongly enhanced.…”

mentioning

confidence: 94%

Single photon transport by a moving atom through sub-wavelength hole

et al. 2016

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Abstract.The results of investigation of photon transport through the subwavelength hole in the opaque screen by using single neutral atom are represented. The basis of the proposed and implemented method is the absorption of a photon by a neutral atom immediately before the subwavelength aperture, traveling of the atoms through the hole and emission of a photon on the other side of the screen. Realized method is the alternative approach to existing for photon transport through a subwavelength aperture: 1) self-sustained transmittance of a photon through the aperture according to the Bethe's model; 2) extra ordinary transmission because of surface-plasmon excitation.The simplest way to transport of photon energy from the one side of opaque screen to another is using of photon transmission through the hole in the screen. Unfortunately as was shown by Bethe [1] and Bouwkamp [2] the efficiency of such transport is low in the case of subwavelength holes. A remarkable discovery about the transmission of light through a subwavelength hole in a metal screen of a finite thickness and a finite conductivity that has been made by Ebbesen et al. [3] has shown that the standard theory of diffraction by small holes is invalid, and, in this case, the transmission of light through the subwavelength hole can be strongly enhanced. The majority of researchers agree that the central role in this phenomenon is played by surface waves, such as surface plasmons.We have proposed and investigated [4] a fundamentally different mechanism by which a photon can be transferred through a subwavelength hole. It is based on the photon transport that involves the participation of a particle other than a plasmon, namely, a neutral atom. In this scheme, a single atom transfers a single photon through a nanohole. Besides the using of a new particle for photon transport it opens up a new possibilities for surface science. It is possible to use such scheme for investigation of van der Waals interaction of atom inside the hollow cylinder [5]. Another application of the described scheme it could be useful for atom -plasmon interaction investigation. Indeed the subwavelength hole is a highly nonlinear plasmonic element. So the interaction of excited atom with such structure opens new way for tailoring the spectral properties of materials [6].The basic idea of the single photon transport by a moving atom is presented in Fig. 1. An atom moving toward a metal screen with a hole absorbs a photon of laser radiation immediately in front of the hole. If the lifetime of the atom is substantially larger than the * Corresponding author: afanasiev@isan.troitsk.ru

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Diffraction Theory

Cited by 750 publications

References 335 publications

Near-field microscopy with a single-photon point-like emitter: Resolution versus the aperture tip?

Near-field microscopy with a single-photon point-like emitter: Resolution versus the aperture tip?

Finite element study of ultrasonic imaging

Single photon transport by a moving atom through sub-wavelength hole

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