Editing Diffraction (section)

=== Single-slit diffraction ===
{{Main|Diffraction formalism}}

[[File:DiffractionSingleSlit Anim.gif|thumb|2D Single-slit diffraction with width changing animation]] 
[[Image:Wave Diffraction 4Lambda Slit.png|right|thumb|Numerical approximation of diffraction pattern from a slit of width four wavelengths with an incident plane wave. The main central beam, nulls, and phase reversals are apparent.]]
[[Image:Single Slit Diffraction (english).svg|right|thumb|Graph and image of single-slit diffraction]]

A long slit of infinitesimal width which is illuminated by light diffracts the light into a series of circular waves and the wavefront which emerges from the slit is a cylindrical wave of uniform intensity, in accordance with the [[Huygens–Fresnel principle]].

An illuminated slit that is wider than a wavelength produces interference effects in the space downstream of the slit.  Assuming that the slit behaves as though it has a large number of point sources spaced evenly across the width of the slit interference effects can be calculated. The analysis of this system is simplified if we consider light of a single wavelength. If the incident light is [[Coherence (physics)#Examples|coherent]], these sources all have the same phase.  Light incident at a given point in the space downstream of the slit is made up of contributions from each of these point sources and if the relative phases of these contributions vary by <math>2\pi</math> or more, we may expect to find minima and maxima in the diffracted light. Such phase differences are caused by differences in the path lengths over which contributing rays reach the point from the slit.

We can find the angle at which a first minimum is obtained in the diffracted light by the following reasoning. The light from a source located at the top edge of the slit interferes destructively with a source located at the middle of the slit, when the path difference between them is equal to {{nowrap|<math>\lambda/2</math>.}} Similarly, the source just below the top of the slit will interfere destructively with the source located just below the middle of the slit at the same angle. We can continue this reasoning along the entire height of the slit to conclude that the condition for destructive interference for the entire slit is the same as the condition for destructive interference between two narrow slits a distance apart that is half the width of the slit. The path difference is approximately <math>\frac{d \sin(\theta)}{2}</math> so that the minimum intensity occurs at an angle <math>\theta_\text{min}</math> given by
<math display="block">d\,\sin\theta_\text{min} = \lambda,</math>
where <math>d</math> is the width of the slit, <math>\theta_\text{min}</math> is the [[Angle of incidence (optics)|angle of incidence]] at which the minimum intensity occurs, and <math>\lambda</math> is the wavelength of the light.

A similar argument can be used to show that if we imagine the slit to be divided into four, six, eight parts, etc., minima are obtained at angles <math>\theta_{n}</math> given by
<math display="block">d\,\sin\theta_{n} = n \lambda,</math>
where <math>n</math> is an integer other than zero.

There is no such simple argument to enable us to find the maxima of the diffraction pattern. The [[diffraction formalism#Quantitative analysis of single-slit diffraction|intensity profile]] can be calculated using the [[Fraunhofer diffraction]] equation as
<math display="block">I(\theta) = I_0 \, \operatorname{sinc}^2 \left( \frac{d \pi}{\lambda} \sin\theta \right),</math>
where <math>I(\theta)</math> is the intensity at a given angle, <math>I_0</math> is the intensity at the central maximum {{nowrap|(<math>\theta = 0</math>),}} which is also a normalization factor of the intensity profile that can be determined by an integration from <math display="inline">\theta = -\frac{\pi}{2}</math> to <math display="inline">\theta = \frac{\pi}{2}</math> and conservation of energy, and {{nowrap|<math>\operatorname{sinc} x = \frac{\sin x}{x}</math>,}} which is the [[unnormalized sinc function]].

This analysis applies only to the [[far field]] ([[Fraunhofer diffraction]]), that is, at a distance much larger than the width of the slit.

From the [[diffraction formalism#Quantitative analysis of single-slit diffraction|intensity profile]] above, if {{nowrap|<math>d \ll \lambda</math>,}} the intensity will have little dependency on {{nowrap|<math>\theta</math>,}} hence the wavefront emerging from the slit would resemble a cylindrical wave with azimuthal symmetry; If {{nowrap|<math>d \gg \lambda</math>,}} only <math>\theta \approx 0</math> would have appreciable intensity, hence the wavefront emerging from the slit would resemble that of [[geometrical optics]].

When the incident angle <math>\theta_\text{i}</math> of the light onto the slit is non-zero (which causes a change in the [[Optical path length|path length]]), the intensity profile in the Fraunhofer regime (i.e. far field) becomes:
<math display="block">I(\theta) = I_0 \, \operatorname{sinc}^2 \left[ \frac{d \pi}{\lambda} (\sin\theta \pm \sin\theta_\text{i})\right]</math>
The choice of plus/minus sign depends on the definition of the incident angle {{nowrap|<math>\theta_\text{i}</math>.}}[[File:Diffraction2vs5.jpg|right|thumb|2-slit (top) and 5-slit diffraction of red laser light]]
[[File:Diffraction-red laser-diffraction grating PNr°0126.jpg|thumb|left|Diffraction of a red laser using a diffraction grating]]
[[File:Diffraction 150 slits.jpg|right|thumb|A diffraction pattern of a 633 nm laser through a grid of 150 slits]]