F = -kx

a = −ω^2*x => ω^2 = k/m => ω = √(k/m)

x∝sin(ωt) => x=(x0)*sin(ωt) => v=ω*(x0)*cos(ωt)

v = ±ω*√(x0^2 - x^2)

sin θ ≈ θ

The central maximum is larger than the slit width.

The central maximum is very much more intense than the other maxima

Each successive maximum is just less than half the intensity of the previous maximum.

The subsidiary maxima decrease in intensity the further out they get.

The central maximum is twice the width of the other maxima, which are all evenly spaced.

θ=λ/b

λ/2 = (b/2)*sinθ

λ′ = (v±v_s)/f

Definition: The Rayleigh criterion states that two sources can resolve if the principal maximum of one source is no closer than the first minimum of the other.

On the left, the images are easily resolved: The blue principal maximum is further away than the first minimum of the red principal maximum. The middle diagram shows the critical case: The red principal maximum is exactly in line with the first blue minimum.

A full mathematical description of a circular aperture tells us that we need to modify the single slit equation by a factor of 1.22. This derivation is beyond the scope of this course, but it tells us that for two images to be just resolved: θ≥1.22λb

Experiment setup

The 'bright fringe' region indicates where constructive interference is found: where waves meet with a path difference = nλ, where n=0,±1,±2,...

Regions labelled ‘dark fringe’ indicates where destructive interference takes place: where waves meet with a path difference = (n+1/2)λ, where n=0,±1,±2,...

Therefore, the double-slit can cause both interference and coherence

Definition

1. Intense, dominant central maximum. 2. Less intense subsequent maxima. 3. The position of these maxima is in the same position as the single-slit pattern.

Diffraction gratings often quote ‘500 lines per mm’. To use this information in the diffraction grating equation, you have to convert this data into the distance between the slits, d. d = 1mm/500 = 2×10−6m

d sinθ = nλ

The two rays of light (red) meet at the first maximum away from the centre. Their path difference is λ. It is important to remember that D>>d, which means we can approximate both of the marked right angles to exactly 90∘ and say that the two angles marked θ (green and blue) are equal.