Waves: Diffraction Gratings

1. Learning Objectives Book Reference : Pages 205-207 Waves: Diffraction Gratings To understand diffraction gratings To understand how changing wavelength and slit size affect the transmitted pattern To understand how the diffraction grating equation is derived To be able to complete diffraction grating related calculations

2. A diffraction grating is plate with many parallel slits in it. Diffraction Gratings : Definition

3. Light passing through each slit is diffracted The Diffracted light wave from adjacent slits interfere, (reinforce each other) in certain directions only Diffraction Gratings : Key Results

4. The central beam is referred to as the “zero order beam” The other beams are numbered outwards on each side: 1st order, 2nd order etc Diffraction Gratings : Terminology

5. How does the diffraction pattern change with wavelength? How does the diffraction pattern change with slit distance? Diffraction Gratings : Experimental Questions Virtual Physics Lab : Waves  Diffraction

6. How does the diffraction pattern change with wavelength? How does the diffraction pattern change with slit distance? Diffraction Gratings : Experimental Findings The angle of diffraction between each beam and the zero order beam increases with increasingwavelength (Blue to Red) The angle of diffraction between each beam and the zero order beam increases with decreasing gap size

7. Each diffracted wavefront reinforces an adjacent wavefront Wavefront at P reinforces wavefront at Y one cycle earlier which in turn reinforces wavefront at R one cycle earlier This forms a new wavefront PYZ which travels in a certain direction and forms a diffracted beam Diffraction Gratings : Analysis 1

8. Formation of nth order beam Wavefront at P reinforces wavefront from Q emitted n cycles earlier. Wavefront from Q has travelled n wavelengths. QY is n sin  = QY/QP (substitute) sin  = n /d(rearrange) dsin = n Diffraction Gratings : Analysis 2 Q Y d  P 

9. Notes • The number of slits per metre N is 1/d • As d decreases the angle of diffraction increases. (As N increases, the angle of diffraction increases) • Maximum number of orders is when  = 90° and hence sin  = 1 • n = d/ • (Rounded down to the nearest whole number) Diffraction Gratings : Analysis 3

10. A laser of wavelength 630nm is directed normally at a diffraction grating with 300 lines per mm. Calculate : • The angle of diffraction for the first two orders [10.9° & 22.2°] • The number of diffracted orders produced [5] Problems 1

11. Light incident normally on a diffraction grating with 600 lines per mm contains wavelengths of 580nm and 586nm only. • How many diffracted orders are seen in the transmitted light [2] • For the highest order calculate the angle between the two diffracted beams [0.58°] Problems 2

12. Light of wavelength 480nm is incident normally on a diffraction grating the 1st order transmitted beams are at 28° to the zero order beam. Calculate: • The number of slits per mm for the grating [1092] • The angle of diffraction for each of the other diffracted orders [69.9°] Problems 3