Slide 1

Slide 2 Example Two identical point sources produce water waves with a wavelength of 0.04 m. The sources are 0.1 m apart. What is the maximum angle for a line of total constructive interference and what is the value of n for this line? Slide 3 Plane water waves If you have a line of point sources, it is called a line source. This produces wavecrests that are straight and parallel to the line source. These are called plane waves. Slide 4 Plane water waves hit a barrier with holes Plane waves hit a barrier that has two openings, or slits in it. The waves eminating from each slit look like those from a point source. A slit thus acts as a point source when plane waves hit the barrier. Slide 5 What is light? Isaac Newton believed that light was made of particles that he called corpuscles. Youngs double slit experiment for light showed an interference pattern that looked like those of water waves. So light is a WAVE! Slide 6 Youngs Double Slit Experiment Bright fringes are maxima (total constructive interference) and dark fringes are minima (total destructive interference). n=0 is the central maximum; n=1 is the first fringe, etc. Slide 7 Measure wavelength of different colors of light Red light spreads out more than blue light. Slide 8 Diffraction When light passes through a slit, it bends around the slit. This effect is called diffraction. A device with many slits is called a diffraction grating. Each slit acts as a point source. Total constructive and total destructive interference result in bright fringes (maxima) and dark fringes (minima). The angles of the maxima are given by Slide 9 Spread in maxima depends on wavelength Red spreads more than blue Blue spreads less than red Slide 10 White light Because the angle (i.e. spread) of bright fringes depends on wavelength, a diffraction grating will separate white light into its spectrum. Slide 11 Wavelengths of Colors Slide 12 Poll If the distance between slits of a diffraction grating is increased, what will happen to the distance between the central maximum and first bright fringe? 1.it will increase (more spread out) 2.it will decrease (less spread out) 3.it will remain the same Slide 13 Poll Which color has a fringe further from the central maximum, red or blue? 1.red 2.blue 3.neither, because their fringes will be at the same location relative to the central maximum Slide 14 Speed of Light Light has a finite speed. According to NIST, the meter was defined to be the length of a certain platinum bar kept at constant temperature in Paris. Using this standard, the speed of light in a vacuum was measured to be Rather than continuing to try to measure the speed of light more precisely, based on the length of a stick in Paris, instead the speed of light was defined as this value, and the meter was redefined to be the distance light travels in 1/299,792,458 s. Slide 15 Speed of light in a medium When light travels through a medium, such as glass for example, then it travels slowe than in a vacuum. As a result, it will have a shorter wavelength. Its wavelength in a medium is related to its wavelength in vacuum by Slide 16 Other types of interference Slide 17 Phase change upon reflection Suppose that light travels from vacuum to glass. It both reflects and transmits at the vacuum/glass surface. The reflected wave will have a phase shift of 180 which corresponds to half a wavelength. If light travels from a slower medium to a faster medium, it does not change phase (in other words, is not shifted by half a wavelength) Slide 18 Interference from multiple reflections thickness, d for total constructive interference