3.3.2.2 Waves: Diffraction

Question 1

What is diffraction?

Answer 1

When waves spread out as they come through a narrow gap or around obstacles

Question 2

What does the amount of diffraction depend on?

Answer 2

The wavelength of the wave compared to the size of the gap

Question 3

How does diffraction varies as you vary the size of the gap?

Answer 3

When gap is a lot bigger than the wavelength, diffraction is unnoticeable.
You get noticeable diffraction when the gap is several wavelengths wide
Most diffraction happens when the gap is the same size as the wavelength.
When the gap is smaller than the wavelength, the wave is mostly reflected back

Question 4

Describe diffraction around obstacles

Answer 4

When a wave meets an obstacle, you get diffraction around the edges, behind the obstacle is the ‘shadow’, where the wave is blocked.

Question 5

How does diffraction vary around obstacles?

Answer 5

The wider the obstacle compared to the wavelength, the less diffraction, so the longer the shadow

Question 6

What should you use if you want to observe a clear diffraction pattern?

Answer 6

Monochromatic, coherent light source.
Or use a colour filter on white light

Question 7

What is monochromatic light?

Answer 7

Light of a single wavelength and frequency

Question 8

Why is white light not good for diffraction patterns?

Answer 8

It has many different wavelengths that diffract by different amounts, so unclear diffraction pattern

Question 9

Describe the diffraction pattern when shining a laser through a single slit

Answer 9

Pattern has a bright central fringe (central maximum) with alternating bright and dark fringes either side of it. This pattern is due to interference - bright fringes are due to constructive interference, where waves arrive at the screen in phase, dark fringes are due to total destructive interference, where waves across the width of the slit arrive at the screen completely out of phase

Question 10

Describe what happens when white light passes through a narrow slit

Answer 10

Diffraction pattern produced, different wavelengths are refracted by different amounts, so pattern produced is more red away from the central maximum, and more blue towards the central maximum, because shorter wavelengths diffract less

Question 11

What is intensity?

Answer 11

Power per unit area

Question 12

How does the width of the central maximum vary?

Answer 12

With the width of the slit and the wavelength of light being diffracted - Increasing slit width decreases amount of diffraction so central maximum is narrower and intensity of central maximum is higher
- Increasing wavelength increases diffraction, central maximum is wider and intensity of central maximum is lower.

Question 13

What is a diffraction grating?

Answer 13

A diffraction grating is a piece of glass or plastic with a large
number of equidistant, closely parallel ‘lines’ or slits.

Question 14

Why is diffraction grating better than double slit?

Answer 14

Interference pattern produced is sharper (bright areas are brighter and dark areas are darker).

Question 15

Why are sharper fringes better?

Answer 15

They make for more accurate measurements

Question 16

What is the diffraction grating equation?

Answer 16

dsintheta = nlambda
(distance between slits * sin angle to the normal = order of maximum * wavelength of the light source)

Question 17

What are diffraction gratings used for?

Answer 17

When you split up light from a star using a diffraction grating, you can see line absorption spectra (spectra with dark lines corresponding to different wavelengths of light that have been absorbed. Each element in the star’s atmosphere absorbs light of different wavelengths.

X-ray crystallography