Interference fringe patterns are not restricted to experiments having the double slit configuration, but can be produced by any event that results in the splitting of light into waves that can be canceled or added together. Because these waves will not arrive at point B in phase (or in step with each other), they will undergo destructive interference to produce a dark region (interference fringe on the screen. As a consequence, the wave from the closest slit should arrive at point B slightly ahead of the wave from the farthest slit. The wave emanating from the slit closer to point B (take for example the slit and point B on the left-hand side of Figure 1) does not have as far to travel to reach its destination as does a wave traveling from the other slit. In contrast, neither of the points B on the screen is positioned equidistant from the two slits, so light must travel a greater distance from one slit to reach point B than from the other. Because the two waves reaching point A possess the necessary requirements for constructive interference, they should add together to produce a bright red interference fringe on the screen. Light waves from each of the slits must travel an equal distance to reach point A on the screen illustrated in Figure 1, and should reach that point still in step or with the same phase displacement. The coherent wavefront of light impacting on the twin slits is divided into two new wavefronts that are perfectly in step with each other. Although Young achieved this coherence through the diffraction of sunlight from the first slit, any source of coherent light (such as a laser) can be substituted for light passing through the single slit. The key to this type of experiment is the mutual coherence between the light waves diffracted from the two slits at the barrier. A screen is placed in the region behind the slits to capture overlapped light rays that have passed through the twin slits, and a pattern of bright red and dark interference bands becomes visible on the screen. Light waves exiting the first slit are then made incident on a pair of slits positioned close together on a second barrier. Red filtered light derived from sunlight is first passed through a slit to achieve a coherent state. The basic setup of the double slit experiment is illustrated in Figure 1. Young coined the term interference fringes to describe the bands and realized that these colored bands could only be produced if light were acting like a wave. However, when he reduced the size of the slits and brought them closer together, the light passing through the slits and onto the screen produced distinct bands of color separated by dark regions in a serial order. Young observed that when the slits were large, spaced far apart and close to the screen, then two overlapping patches of light formed on the screen. Light passing through the slits was then allowed to fall onto a screen. Using sunlight diffracted through a small slit as a source of coherent illumination, he projected the light rays emanating from the slit onto another screen containing two slits placed side by side. In order to test his hypothesis, Young devised an ingenious experiment. In contrast, when two waves meet that are out of step (the crest of one meets the trough of another), the waves should cancel and produce a flat surface in that area. If the two waves are in step (the crests meet), then they should combine to make a larger wave. Where two opposing water waves meet, they should react in a specific manner to either reinforce or destroy each other. Young's experiment was based on the hypothesis that if light were wave-like in nature, then it should behave in a manner similar to ripples or waves on a pond of water. The slider labeled Distance Between Slits can be utilized to vary the distance between the slits and produce corresponding variations in the interference intensity distribution patterns. The results of interference between the diffracted light beams can be visualized as light intensity distributions on the dark film. This light is then projected onto another screen that has twin (or double) slits, which again diffracts the incident illumination as it passes through. The tutorial initializes with rays from the sun being passed through a single slit in a screen to produce coherent light. This interactive tutorial explores how coherent light waves interact when passed through two closely spaced slits. Because he believed that light was composed of waves, Young reasoned that some type of interaction would occur when two light waves met. In 1801, an English physicist named Thomas Young performed an experiment that strongly inferred the wave-like nature of light.
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