Near field diffraction of cylindrical convex gratings

Torcal-Milla, Francisco José; Sanchez‐Brea, Luis Miguel; Bernabéu, Eusebio

doi:10.1088/2040-8978/17/3/035601

Cited by 4 publications

(4 citation statements)

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“…In the same fashion, by taking zeroth and third diffraction orders, constructive interference appears at distances z = (2m − 1)z T /4 but with a periodicity half of that of the diffraction grating [3]. We show in figure 2 four examples of Talbot effect obtained analytically from the intensity calculated by means of the propagation of the grating transmittance by using the Fresnel kernel with plane wave illumination, in a similar way as it is made in [4]. The period of the gratings, placed at z = 0, is p = 20 µm, and the Talbot distance results z T = 1.26 mm and z T = 1.5 mm for λ = 632 nm and λ = 532 nm, respectively.…”

Section: Introductionmentioning

confidence: 73%

“…It appears when a diffraction grating is illuminated with a collimated monochromatic beam. This effect has been found also for other types of waves, besides electromagnetic, such as mechanical waves in water [3], and it has been analysed under many configurations, for cylindrical gratings [4], with non-collimated beams, with polychromatic illumination [5,6], with rough diffraction gratings [7], all of them resulting in very interesting properties and behaviours. Besides, it has applications in many different branches of science and technology such as machine tool, optical encoders, dimensional metrology, and so on [8].…”

Section: Introductionmentioning

confidence: 86%

“…Now, the illumination beam is slightly divergent. With diverging or converging light, the period of the self-images increases or decreases, respectively, as we separate from the grating plane [4]. In addition, the source is no longer monochromatic but it has a wide spectrum.…”

Section: Non-coherent Illuminationmentioning

confidence: 99%

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A diffraction experiment at the near field: the homemade Talbot effect

Torcal-Milla¹

2022

Phys. Educ.

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Diffraction refers to a kind of optical phenomena which occurs when light approaches an element (object or aperture) whose features are in the range of the illuminating wavelength (small apertures, sharp edges). It can be explained by means of the undulatory nature of light or also geometrically by using simple ray optics. Diffraction phenomena are impressive and not intuitive, so it makes them very interesting to bring examples to the classroom. The most popular diffraction experiments show effects in Fraunhofer regime, that is to be said, far from the diffractive object. Common examples are the single or double slit experiments. In this manuscript, we propose and show a less common diffractive effect that occurs in the Fresnel regime, near to the diffractive object. It is the Talbot effect or self-imaging phenomenon, which appears by illuminating a diffraction grating with a collimated monochromatic beam. It consists of the apparition of replicas (self-images) of the grating intensity pattern at periodic distances, multiples of the so-called Talbot distance. We show how this effect may be shown into the classroom with cheap and easy to find elements. In addition, we take advantage of its dependence on the coherence degree of the source to introduce the concept of optical coherence and show its effect on the contrast of the Talbot self-images. These experiments could be appropriate for undergraduate students or introductory physics courses.

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Section: Introductionmentioning

confidence: 73%

Section: Introductionmentioning

confidence: 86%

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A diffraction experiment at the near field: the homemade Talbot effect

Torcal-Milla¹

2022

Phys. Educ.

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“…As can be observed, Talbot self-images converge to the focal plane. It is important to notice that the period of the self-images must be calculated under paraxial approximation since the lens also curves the self-images far from the optical axis in a similar way to that is shown in [18,19]. Theoretically, the period has a linear dependence with z, p az b ′ = + .…”

Section: Analytical Approachmentioning

confidence: 94%

Near-field diffraction-based focal length determination technique

Torcal-Milla

Sanchez‐Brea

2017

Optics and Lasers in Engineering

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An accurate and simple technique for determining the focal length of a lens is presented. It consists of measuring the period of the fringes produced by a diffraction grating at the near field when it is illuminated with a beam focused by the unknown lens. In paraxial approximation, the period of the fringes varies linearly with the distance. After some calculations, a simple extrapolation of data is performed to obtain the locations of the principal plane and the focal plane of the lens. Thus, the focal length is obtained as the distance between the two mentioned planes. The accuracy of the method is limited by the collimation degree of the incident beam and by the algorithm used to obtain the period of the fringes. We have checked the technique with two commercial lenses, one convergent and one divergent, with nominal focal lengths (+100 ± 1) mm and (−100 ± 1) mm respectively. We have experimentally obtained the focal lengths resulting into the interval given by the manufacturer but with an uncertainty of 0.1%, one order of magnitude lesser than the uncertainty given by the manufacturer.

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