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Single-Slit Diffraction (HL) (HL IB Physics)

Revision Note

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Single Slit Intensity Pattern

Single Slit Diffraction Pattern

  • The diffraction pattern of monochromatic light passing through a single rectangular slit, is a series of light and dark fringes on a faraway screen
  •  This is similar to a double slit diffraction pattern: 
    • The bright fringes are also areas of maximum intensity, produced by the constructive interference of each part of the wavefront as it passes through the slit
    • The dark fringes are also areas of zero or minimum intensity, produced by the destructive interference of each part of the wavefront as it passes through the slit

single-slit-diffraction

The diffraction pattern produced by a laser beam diffracted through a single slit onto a screen is different to the diffraction pattern produced through a double slit

  • However, the single and double-slit diffraction patterns are different
  • The central maximum of the diffraction pattern is:
    • Much wider and brighter than the other bright fringes
    • Much wider than that of the double-slit diffraction pattern
  • On either side of the wide central maxima for the single slit diffraction pattern are much narrower and less bright maxima
    • These get dimmer as the order increases

Single Slit Intensity Pattern

  • If a laser emitting blue light is directed at a single slit, where the slit width is similar in size to the wavelength of the light, its intensity pattern will be as follows:

Diffraction with a laser, downloadable AS & A Level Physics revision notes

The intensity pattern of blue laser light diffracted through a single slit

  • The features of the single slit intensity pattern are: 
    • The central bright fringe has the greatest intensity of any fringe and is called the central maximum
    • The dark fringes are regions with zero intensity
    • Moving away from the central maxima either side, the intensity of each bright fringe gets less

Changes in Wavelength

  • When the wavelength passing through the gap is increased then the wave diffracts more
  • This increases the angle of diffraction of the waves as they pass through the slit
    • So the width of the bright maxima is also increased
  • Red light
    • Which has the longest wavelength of visible light
    • Will produce a diffraction pattern with wide fringes
    • Because the angle of diffraction is wider
  • Blue light
    • Which has a much shorter wavelength
    • Will produce a diffraction pattern with narrow fringes
    • Because the angle of diffraction is narrower

9-2-1-fringe-width-depends-on-the-wavelength-of-light-ib-hl

Fringe width depends on the wavelength of the light 

  • If the blue laser is replaced with a red laser:
    • There is more diffraction as the waves pass through the single slit
    • So the fringes in the intensity pattern would therefore be wider

Diffraction graph, downloadable AS & A Level Physics revision notes

The intensity pattern of red laser light shows longer wavelengths diffract more than shorter wavelengths

Changes in Slit Width

  • If the slit was made narrower:
    • The angle of diffraction is greater
    • So, the waves spread out more beyond the slit
  • The intensity graph when the slit is made narrower will show that: 
    • The intensity of the maxima decreases
    • The width of the central maxima increases
    • The spacing between fringes is wider

Single Slit Equation

  • These properties of wavelength and slit width for single slit diffraction for the first minima can be explained using the equation:

theta equals lambda over b

  • Where:
    • θ = the angle of diffraction of the first minima (°)
    • λ = wavelength (m)
    • b = slit width (m)
  • Hence,
    • The longer the wavelength, the larger the angle of diffraction
    • The narrower the slit width then the larger the angle of diffraction

9-3-2-slit-width

Slit width and angle of diffraction are inversely proportional. Increasing the slit width leads to a decrease in the angle of diffraction, hence the maxima appear narrower

Single Slit Geometry

  • The diffraction pattern made by waves passing through a slit of width b can be observed on a screen placed a large distance away

oRULRXAE_9-2-2-diffraction-geometry-ib-hl

The geometry of single-slit diffraction

  • If the distance, D, between the slit and the screen is considerably larger than the slit width, D greater than greater than b:
    • The light rays can be considered as a set of plane wavefronts that are parallel to each other

9-2-2-single-slit-geometry

Determining the path difference using two parallel waves

  • For two paths, r1 and r2, travelling parallel to each other at an angle, θ, between the normal and the slit, the path difference will be:

path difference = r1 − r2b over 2 sin space theta

  • For a minima, or area of destructive interference:

The path difference must be a half-integral multiple of the wavelength

path difference = fraction numerator n lambda over denominator 2 end fraction

  • Equating these two equations for path difference:

fraction numerator n lambda over denominator 2 end fraction equals b over 2 sin space theta

n lambda equals b sin space theta

  • Where n is a non-zero integer number, n = 1, 2, 3...

  • Since the angle θ is small, the small-angle approximation may be used: sin space theta almost equal to theta

n lambda equals b theta

  • Therefore, the first minima, n = 1, occurs at:

lambda equals b theta

  • This leads to the equation for angle of diffraction of the first minima:

theta equals lambda over b

Worked example

A group of students are performing a diffraction investigation where a beam of coherent light is incident on a single slit with width, b.

The light is then incident on a screen which has been set up a distance, D, away.

9-2-2-we1-intensity-of-interference-ib-hl

A pattern of light and dark fringes is seen.

The teacher asks the students to change their set-up so that the width of the first bright maximum increases.

Suggest three changes the students could make to the set-up of their investigation which would achieve this.

Step 1: Write down the equation for the angle of diffraction

theta equals lambda over b

    • The width of the fringe is related to the size of the angle of diffraction, θ

Step 2: Use the equation to determine the factors that could increase the width of each fringe

Change 1

    • The angle of diffraction, θ, is inversely proportional to the slit width, b

theta proportional to 1 over b

    • Therefore, reducing the slit width would increase the fringe width

Change 2

    • The angle of diffraction, θ, is directly proportional to the wavelength, λ

theta proportional to lambda

    • Therefore, increasing the wavelength of the light would increase the fringe width

Change 3

    • The distance between the slit and the screen will also affect the width of the central fringe
    • A larger distance means the waves must travel further hence, will spread out more
    • Therefore, moving the screen further away would increase the fringe width

Double Slit Modulation

    • When light passes through a double slit two types of interference occur:
      • The diffracted rays passing through one slit interfere with the rays passing through the other
      • Rays passing through the same slit interfere with each other
    • This produces a double-slit intensity pattern where the single-slit intensity pattern modulates (adjusts) the intensity of the light on the screen
      • It looks like a double-slit interference pattern inscribed in the single-slit intensity pattern

modulated-double-slit-internsity-pattern

The double slit interference pattern is modulated inside the single slit intensity pattern

  • The single-slit intensity pattern has a distinctive central maximum and subsequent maxima at lower intensity
  • The double-slit interference pattern has equally spaced intensity peaks with maxima of equal intensity
  • Together, the combined double slit intensity pattern has equally spaced bright fringes but now within a single slit 'envelope

double-slit-modulation

Combined single-slit intensity pattern and double-slit interference pattern

  • This is assuming that:
    • The slit width is not negligible
    • The distance between the slits is much greater than their width 

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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.