5.2: 1D single slit

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1D: a single slit produces a bright central maximum, with subsidiary maxima and minima. We divide the single slit (width \(a\) ) into Huygens sources. Cancellation produces minima at \(\sin \theta=m \lambda / a\), where \(m=1,2\) etc. In the limit of small Huygens sources, phasor addition quantifies the intensity as function of angle \(\theta\). In Young's experiment, the diffraction term modulates the interference term. It is worth revising the previous page to see the resultant interference-diffraction pattern for both the Young's experiment with laser light and the 'single photon' interference pattern.

Learning Objectives

Bright central maximum, subsidiary maxima and minima.
Huygens construction gives minima at \(\sin \theta=m \lambda / a\), \(m=1,2\) etc.
Phasor addition gives the intensity as function of angle.

Table \(\PageIndex{1}\)
Links to related material
Diffraction, shadows, beams, Huygens' construction. Diffraction of light and sound. Water waves in a ripple tank. Shadows and beams with water waves of short wavelength. Diffraction at longer wavelengths. X-ray, neutron and electron diffraction
Diffraction from a single slit. Young's experiment with finite slits. Diffraction from a single slit:Huygens' construction. Phasor diagrams give Iq. Varying the slit width. Young's experiment with finite slit width: Iq shows both interference and diffraction effects.
The quantum mechanics of cricket A light-hearted discussion to illustrate why we don't notice quantum interference in everyday life.
Diffraction gratings and spectroscopy. Adding phasors with 2, 3, 4 and many slits: Diffraction gratings. Diffraction from monochromatic sources. Continuous spectra and line spectra, absorption and emission spectra. The hydrogen spectrum and the origins of quantum mechanics.
Poisson-Arago dot The bright dot at the centre of the shadow: Poisson's argument against the wave nature of light. A modern recreation of Arago's experiment.
Rayleigh criterion and the Airy disc: Aperture and resolution Circular apertures in optics. Diffraction pattern from a circular aperture. The Airy disc. Resolving two point sources: Rayleigh's criterion. When is the eye diffraction limited? The resolution of telescopes. Radio telescopes and arrays
X-ray diffraction: Bragg's law The atomic lattice as a diffraction grating. Diffraction requires wavelengths less than 0.1 nm. X-ray diffraction.
Holography Forming a hologram: beam splitter, object and reference beams, interference at the film. Recreating a hologram: coherence beam and hologram plate.
Diffraction Experiments Single slit diffraction, diffraction gratings.

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