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Diffraction Gratings (HL) (HL IB Physics)

Revision Note

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The Diffraction Grating

  • A diffraction grating is a piece of optical equipment that also creates a diffraction pattern when light is passed through it
  • Diffraction gratings diffract::
    • Monochromatic light into bright and dark fringes
    • White light into its different wavelength components

laser-diffraction-grating-set-up

A laser beam is diffracted through a diffraction grating

  • A diffraction grating consists of a large number of very thin, equally spaced parallel slits carved into a glass plate

diffraction-grating

A diffraction grating consists of many parallel equally spaced slits cut into the glass plate

diffraction-grating-magnified-view

When you look closely at a diffraction grating you can see the curved shape of the slits

The Diffraction Grating Equation

  • Diffraction gratings are useful because they create a sharper pattern than a double slit

    • This means their bright fringes are narrower and brighter while their dark regions are wider and darker

diffraction-grating-set-uo-with-fringes

A diffraction grating is used to produce narrow bright fringes when laser light is diffracted through it

  • Just like for single and double-slit diffraction the regions where constructive interference occurs are also the regions of maximum intensity
  • Their location can be calculated using the diffraction grating equation

Grating equation, downloadable AS & A Level Physics revision notes

  • Where:
    • n is the order of the maxima, the number of the maxima away from the central (= 0)
    • d is the distance between the slits on the grating (m)
    • θ is the angle of diffraction of the light of order n from the normal as it leaves the diffraction grating (°)
    • λ is the wavelength of the light from the source (m)

Number of Slits

  • Increasing the number of slits increases the number and intensity of the maxima in the intensity pattern
    • This is because more slits means more diffraction and more constructive interference

9-3-3-multiple-slit-diffraction

The combined diffraction and interference patterns, called the intensity pattern, for light interfering through different numbers of slits. The maximum intensity increases as the number of slits increases, so the intensity in each graph is relative to that number of slits only

Slit Spacing

  • Diffraction gratings come in different sizes
    • The sizes are determined by the number of lines per millimetre (lines / mm) or lines per m
    • This is represented by the symbol N
  • d can be calculated from N using the equation
    • If is given in terms of lines per mm then will be in mm
    • If is given in terms of lines per m then will be in m

diffraction-grating-sizes

Diffraction gratings come in different sizes according to the number of lines per mm

Angular Separation

  • The angular separation of each maxima is calculated by rearranging the grating equation to make θ the subject
  • The angle θ is taken from the centre meaning the higher orders of n are at greater angles of diffraction

Angular separation, downloadable AS & A Level Physics revision notes

Angular separation increases as the order of maxima increases

  • The angular separation between two angles is found by subtracting the smaller angle from the larger one
  • The angular separation between the first and second maxima at n1 and n2 is θ2θ1

Orders of Maxima

  • The maximum angle of diffraction with which maxima can be seen is when the beam is at right angles to the diffraction grating
    • This means θ = 90o and sin θ = 1

  • The highest order of maxima visible is therefore calculated by the equation:

  • Since n is an integer number of maxima, if the value obtained is a decimal it must be rounded down to determine the highest-order visible
    • E.g If n is calculated as 2.7 then n = 2 is the highest-order visible

The Diffraction of White Light

  • A source of white light diffracted through a diffraction grating will produce the following diffraction pattern:
    • It is different to that produced by a double or single slit
    • The first-order spectrum = 1 is used for analysis
  • The central maximum is a very thin bright strip because each wavelength interferes here constructively
    • It is surrounded by wide dark destructive interference fringes
  • All other maxima are composed of a spectrum
  • Separate diffraction patterns can be observed for each wavelength of light
    • The shortest wavelength (violet / blue) would appear nearest to the central maximum because it is diffracted the least
    • The longest wavelength (red) would appear furthest from the central maximum because it is diffracted the most
  • The colours look blurry and further away from the central maximum, the fringe spacing gets so small that the spectra eventually merge without any space between them
    • As the maxima move further away from the central maximum, the wavelengths of blue observed decrease and the wavelengths of red observed increase

ib-white-light-diffraction-grating

The diffraction pattern of white light diffracted through a diffraction grating

Worked example

An experiment was set up to investigate light passing through a diffraction grating with a slit spacing of 1.7 µm. The fringe pattern was observed on a screen. The wavelength of the light is 550 nm.Worked Example: Diffraction Grating, downloadable AS & A Level Physics revision notes

Calculate the angle α between the two second-order lines.

Worked example - diffraction grating equation (2), downloadable AS & A Level Physics revision notes

Exam Tip

Take care that the angle θ is the correct angle taken from the centre and not the angle taken between two orders of maxima.

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Ashika

Author: Ashika

Ashika graduated with a first-class Physics degree from Manchester University and, having worked as a software engineer, focused on Physics education, creating engaging content to help students across all levels. Now an experienced GCSE and A Level Physics and Maths tutor, Ashika helps to grow and improve our Physics resources.