Light, Reflection and Refraction

1. Light, Reflection and Refraction www.assignmentpoint.com

2. Electromagnetic Waves • Magnetic field wave perpendicular to an electric field wave • All objects emit EMWs. •  Temp EMW • Electromagnetic spectrum • Range of all frequencies of light • Visible light is a very small portion of that entire spectrum. www.assignmentpoint.com

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4. c • Speed of Light - 3.00 x 108m/s. • = (wavelength) x (frequency) • c = ƒ www.assignmentpoint.com

5. Example • AM Radio waves • 5.4 x 105 Hz • 1.7 x 106 Hz •  = ? www.assignmentpoint.com

6. Visible Light • Part of the EMS humans can see • Red - 750nm (x10-9m) • Purple - 380nm • Bees, Birds – UV • Snakes – IR www.assignmentpoint.com

7. Reflection • Light waves usually travel in straight paths • Change in substance changes direction • Opaque - does not permit light • some light reflected • some light absorbed as heat www.assignmentpoint.co m

8. Reflection • Texture affects reflection • Diffuse reflection (rough) • reflects light in many different directions, • Specular reflection (smooth) • reflects light in only one direction • Smooth – variations in surface  www.assignmentpoint.com

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10. Mirrors • Light striking a mirror reflects at the same angle that it struck the mirror www.assignmentpoint.com

11. Flat Mirrors • p = q • p- objects distance to the mirror • q - distance from the mirror to the image • Virtual image • Does not exist • Made by our eyes www.assignmentpoint.com

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13. Ray Diagrams • Used to predict the location of the image of an object www.assignmentpoint.com

14. Concave Spherical Mirrors • Reflective surface is on the interior of a curved surface • C – center of curvature • R – Radius (distance to C) • f – Focal Point (1/2 R) • Principal axis • any line that passes through C • usually oriented with an object www.assignmentpoint.com

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16. Mirror Equations • 1/object distance + 1/image distance = 1/focal length 1/p + 1/q = 1/f • Magnification (M) = Image height/object height (h / h) - (q / p) • M = h / h = - (q / p) www.assignmentpoint.com

17. Sign of Magnification www.assignmentpoint.com

18. Concave Spherical Mirror Rules • A ray traveling through C will reflect back through C • A ray traveling through (f) will reflect parallel to the PA • A ray traveling to the intersection of the PA and the mirror will reflect at the same angle below the PA. • A ray traveling parallel to PA will reflect through the focal point www.assignmentpoint.com

19. Ray Diagrams • Draw three rays • The image forms at the point of intersection • Example • f = 10.0cm • p = 30.0cm • h = 3.00cm www.assignmentpoint.com

20. Convex Spherical Mirrors • Reflective surface is on the outside of the curve. • The points f and C are located behind the mirror • negative www.assignmentpoint.com

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22. Rules • A ray parallel to the PA will reflect directly away from f. • A ray towards f will reflect parallel to the PA • A ray towards C will reflect directly away from C. • A ray to the intersection of PA and mirror will reflect at the same angle below the OA. • Trace the 3 diverging lines back through the mirror to reveal the location of the image which is always virtual www.assignmentpoint.com

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24. Example • f = -8.00cm • p= 10.0cm • h = 3cm www.assignmentpoint.com

25. Parabolic Mirrors • Rays that hit spherical mirrors far away from the OA often reflect though other points causing fuzzy images, spherical aberration. • Telescopes use parabolic mirrors as they ALWAYS focus the rays to a single point. www.assignmentpoint.com

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27. Refraction • Substances that are transparent or translucent allow light to pass though them. • Changes direction of light • Due to the differences in speed of light www.assignmentpoint.com

28. Analogy • A good analogy for refracting light is a lawnmower traveling from the sidewalk onto mud www.assignmentpoint.com

29. Index of Refraction (n) • The ratio of the speed of light in a vacuum to the speed of light in a medium •  n -  c www.assignmentpoint.com

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32. Snell’s Law • ni(sini) = nr(sinr) • r = sin-1{(ni/ nr)(sini)} • Example • i = 30.0⁰ • ni = 1.00 • nr = 1.52 www.assignmentpoint.com

33. i = 30.0⁰ • ni = 1.00 • nr = 1.52 www.assignmentpoint.com

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35. Total Internal Reflection • If the angle of incidence of a ray is greater than a certain critical angle the ray will reflect rather than reflect • This principal is responsible for the properties of fiber optic cables. • Remember the lawn mower analogy… www.assignmentpoint.com

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37. Critical Angle • sin Θc = nr / ni • As long as nr < ni • What is the critical angle for light traveling from Diamond to Air? www.assignmentpoint.com

38. nr = 1.000 ni = 2.419 www.assignmentpoint.com

39. Thin Lenses • Converging • Diverging • f- curve of lens & index of refraction www.assignmentpoint.com

40. Converging Lens Diagram • Ray parallel to PA, refracts through far focal point • Ray through center of lens, continues straight line • Ray through near focal point, refracts through lens, continues parallel to PA • Treat lens as though it were a flat plane. www.assignmentpoint.com

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42. Diverging Lens Diagram • Because the rays that enter a diverging lens do not intersect a virtual image is formed by tracing back the refracted rays. • Ray 1 - parallel to PA, refracts away from near f, trace back to near f. • Ray 2 - ray toward far f, refracts parallel to PA, trace back parallel to PA • Ray 3 - ray through center, continues straight, trace back toward object www.assignmentpoint.com

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44. Sign Conventions for Lens www.assignmentpoint.com

45. Converging Lens Example • p = 30.0cm • f = 10.cm www.assignmentpoint.com

46. Diverging Lens Example • p = 12.5cm • f = -10.0cm www.assignmentpoint.com