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Young’s Double Slit Experiment
Although Christiaan Huygens thought that light was a wave, Isaac Newton did not.
Newton felt that there were other explanations for color, and for the interference and
diffraction effects that were observable at the time. Owing to Newton’s tremendous
stature, his view generally prevailed. The fact that Huygens’s principle worked was
not considered evidence that was direct enough to prove that light is a wave. The
acceptance of the wave character of light came many years later when, in 1801, the
English physicist and physician Thomas Young (1773–1829) did his now-classic
double slit experiment (see Figure 1).

Figure 1. Young’s double slit experiment. Here pure-wavelength light sent through a pair of vertical
slits is diffracted into a pattern on the screen of numerous vertical lines spread out horizontally.
Without diffraction and interference, the light would simply make two lines on the screen.

Why do we not ordinarily observe wave behavior for light, such as observed in
Young’s double slit experiment? First, light must interact with something small, such
as the closely spaced slits used by Young, to show pronounced wave effects.
Furthermore, Young first passed light from a single source (the Sun) through a single
slit to make the light somewhat coherent. By coherent, we mean waves are in phase or
have a definite phase relationship. Incoherent means the waves have random phase
relationships. Why did Young then pass the light through a double slit? The answer to
this question is that two slits provide two coherent light sources that then interfere
constructively or destructively. Young used sunlight, where each wavelength forms its
own pattern, making the effect more difficult to see. We illustrate the double slit
experiment with monochromatic (single λ) light to clarify the effect. Figure 2 shows
the pure constructive and destructive interference of two waves having the same
wavelength and amplitude.
 Figure 2. The amplitudes of waves add. (a) Pure constructive interference is obtained when identical
waves are in phase. (b) Pure destructive interference occurs when identical waves are exactly out of
phase, or shifted by half a wavelength.

When light passes through narrow slits, it is diffracted into semicircular waves, as
shown in Figure 3a. Pure constructive interference occurs where the waves are crest to
crest or trough to trough. Pure destructive interference occurs where they are crest to
trough. The light must fall on a screen and be scattered into our eyes for us to see the
pattern. An analogous pattern for water waves is shown in Figure 3b. Note that
regions of constructive and destructive interference move out from the slits at well-
defined angles to the original beam. These angles depend on wavelength and the
distance between the slits, as we shall see below.

Figure 3. Double slits produce two coherent sources of waves that interfere. (a) Light spreads out
(diffracts) from each slit, because the slits are narrow. These waves overlap and interfere constructively
(bright lines) and destructively (dark regions). We can only see this if the light falls onto a screen and is
scattered into our eyes. (b) Double slit interference pattern for water waves are nearly identical to that
for light. Wave action is greatest in regions of constructive interference and least in regions of
destructive interference. (c) When light that has passed through double slits falls on a screen, we see a
pattern such as this.
To understand the double slit interference pattern, we consider how two waves travel
from the slits to the screen, as illustrated in Figure 4. Each slit is a different distance
from a given point on the screen. Thus different numbers of wavelengths fit into each
path. Waves start out from the slits in phase (crest to crest), but they may end up out
of phase (crest to trough) at the screen if the paths differ in length by half a
wavelength, interfering destructively as shown in Figure 4a. If the paths differ by a
whole wavelength, then the waves arrive in phase (crest to crest) at the screen,
interfering constructively as shown in Figure 4b. More generally, if the paths taken by
the two waves differ by any half-integral number of wavelengths [(1/2)λ, (3/2)λ,
(5/2)λ, etc.], then destructive interference occurs. Similarly, if the paths taken by the
two waves differ by any integral number of wavelengths (λ, 2λ, 3λ, etc.), then
constructive interference occurs.

Figure 4. Waves follow different paths from the slits to a common point on a screen. (a) Destructive
interference occurs here, because one path is a half wavelength longer than the other. The waves start
in phase but arrive out of phase. (b) Constructive interference occurs here because one path is a whole
wavelength longer than the other. The waves start out and arrive in phase.
Figure 5. The paths from each slit to a common point on the screen differ by an amount dsinθ,
assuming the distance to the screen is much greater than the distance between slits (not to scale here).

Figure 5 shows how to determine the path length difference for waves traveling from
two slits to a common point on a screen. If the screen is a large distance away
compared with the distance between the slits, then the angle θ between the path and a
line from the slits to the screen (see the figure) is nearly the same for each path. The
difference between the paths is shown in the figure; simple trigonometry shows it to
be d sin θ, where d is the distance between the slits. To obtain constructive
interference for a double slit, the path length difference must be an integral multiple
of the wavelength, or d sin θ = mλ, for m = 0, 1, −1, 2, −2,... (constructive).

Similarly, to obtain destructive interference for a double slit, the path length
difference must be a half-integral multiple of the wavelength, or

dsinθ=(m+1/2)λ, for m=0,1,−1,2,−2,… (destructive)

where λ is the wavelength of the light, d is the distance between slits, and θ is the
angle from the original direction of the beam as discussed above. We
call m the order of the interference. For example, m = 4 is fourth-order interference.
Figure 6. The interference pattern for a double slit has an intensity that falls off with angle. The
photograph shows multiple bright and dark lines, or fringes, formed by light passing through a double
slit.

The equations for double slit interference imply that a series of bright and dark lines
are formed. For vertical slits, the light spreads out horizontally on either side of the
incident beam into a pattern called interference fringes, illustrated in Figure 6. The
intensity of the bright fringes falls off on either side, being brightest at the center. The
closer the slits are, the more is the spreading of the bright fringes. We can see this by
examining the equation d sin θ = mλ, for m = 0, 1, −1, 2, −2,....

For fixed λ and m, the smaller d is, the larger θ must be, since sinθ=mλ/d. This is
consistent with our contention that wave effects are most noticeable when the object
the wave encounters (here, slits a distance d apart) is small. Small d gives large θ,
hence a large effect.
 EXAMPLE 1. FINDING A WAVELENGTH FROM AN INTERFERENCE
PATTERN

Suppose you pass light from a He-Ne laser through two slits separated by 0.0100 mm
and find that the third bright line on a screen is formed at an angle of 10.95º relative to
the incident beam. What is the wavelength of the light?

Strategy

The third bright line is due to third-order constructive interference, which means
that m = 3. We are given d = 0.0100 mm and θ = 10.95º. The wavelength can thus be
found using the equation d sin θ = mλ for constructive interference.

Solution

The equation is d sin θ = mλ. Solving for the wavelength λ gives
λ=dsinθ/m.
Substituting known values yields
λ=(0.0100 nm)(sin10.95∘ )/3
=6.33×10−4 nm=633 nm

Discussion

To three digits, this is the wavelength of light emitted by the common He-Ne laser.
Not by coincidence, this red color is similar to that emitted by neon lights. More
important, however, is the fact that interference patterns can be used to measure
wavelength. Young did this for visible wavelengths. This analytical technique is still
widely used to measure electromagnetic spectra. For a given order, the angle for
constructive interference increases with λ, so that spectra (measurements of intensity
versus wavelength) can be obtained.

EXAMPLE 2. CALCULATING HIGHEST ORDER POSSIBLE

Interference patterns do not have an infinite number of lines, since there is a limit to
how big m can be. What is the highest-order constructive interference possible with
the system described in the preceding example?

Strategy and Concept

The equation d sin θ = mλ (for m = 0, 1, −1, 2, −2,... ) describes constructive
interference. For fixed values of d and λ, the larger m is, the larger sin θ is. However,
the maximum value that sin θ can have is 1, for an angle of 90º. (Larger angles imply
that light goes backward and does not reach the screen at all.) Let us find
which m corresponds to this maximum diffraction angle.

Solution
Solving the equation d sin θ = mλ for m gives
λ=dsinθ/m.
Taking sin θ = 1 and substituting the values of d and λ from the preceding example
gives
m=(0.0100 mm)(1) ≈15.8
633 nm
Therefore, the largest integer m can be is 15, or m = 15.

Discussion

The number of fringes depends on the wavelength and slit separation. The number of
fringes will be very large for large slit separations. However, if the slit separation
becomes much greater than the wavelength, the intensity of the interference pattern
changes so that the screen has two bright lines cast by the slits, as expected when light
behaves like a ray. We also note that the fringes get fainter further away from the
center. Consequently, not all 15 fringes may be observable.