Chapter 17 Reflection Refraction Reflection When light rays
- Slides: 51
Chapter 17 Reflection & Refraction
Reflection • When light rays bounce back off of a medium boundary
Refraction • The bending of light rays when passing from one medium to another
Ray • A straight line path representing the direction of a light wave
Regular Reflection • Reflection off of a smooth surface which results in reflected wave that are parallel
Regular Reflection • Produce good images • Mirrors give regular reflections
Diffuse Reflection • Reflection off of a rough surface which results in reflected waves that are not parallel
Diffuse Reflection • Because light waves are scattered all over the place, no image can be seen
Law of Reflection • The angle of reflection equals the angle of incident
Law of Reflection a b b = a Normal
Optical Density • How fast light passes through a substance as compared to the speed of light in a vacuum.
Optical Density • As optical density increases, the speed in which light passes decreases
Index of Refraction (n) • Ratio of the speed of light in a vacuum to the speed of light in a material
Indices of Refraction • Vacuum: n = 1. 00 • Air: n = 1. 0003 • Water: n = 1. 33 • Ethanol: n = 1. 36
Indices of Refraction • Crown glass: n = 1. 52 • Quartz: n = 1. 54 • Flint glass: n = 1. 61 • Diamond: n = 2. 42
Speed of Light in Other Substances nsub = c vsub
Speed of Light in Other Substances vsub = c nsub
Solve for the speed of light in each of the following: water (n = 1. 33) crown glass (n = 1. 52) diamond (n = 2. 42)
Solve for the speed of light in a substance with an optical density of 1. 50:
Snell’s Law • The ratio of the sine of the angle of incidence over the sine of the angle of refraction is constant for any substance
Snell’s Law n = sin ai sin ar
Snell’s Law ni sin ai = nr sin ar
Snell’s Law ai n 1 = air ar n 2 = water
Draw a model with a light ray passing from one medium to another more optically dense medium. Include reflection & refraction
A light ray from air (nair = 1. 00) & strikes glass (nglass = 1. 52) with an incident angle of o 30. 0. Calculate the angle of refraction:
A light ray from air (nair = 1. 00) strikes glass (nglass = 1. 61) with an o incident angle of 36. 9. Calculate the angle of refraction:
A light ray from air (nair = 1. 00) & strikes diamond (ndiamd = 2. 42) with an incident angle o of 45. 0. Calculate the angle of refraction:
A light ray incident from air (nair = 1. 00) at o 45. 0 passes into an unknown substance at o 30. 0. Calculate its index of refraction:
Total Internal Reflection • When light passes from a more optically dense substance to a less optically dense one, the angle of refraction > the angle of incident
b a
Total Internal Reflection (TIR) • When the angle of o refraction 90 , total internal reflection occurs.
Calculate the angles where TIR occurs when light passes from the following to air: water (n = 1. 33) crown glass (n = 1. 52) diamond (n = 2. 42)
Applications & Effects • Prisms • Fiber Optics • Mirages • Red Sunsets • Rainbows
Prisms • When light pass through a prism the various wavelengths of light are dispersed or separated into a spectrum
Prisms
Fiber Optics • A light wave can pass through a thin glass thread surrounded by a reflective substance. Even if the glass thread is bent, the wave passes through as it reflects off the sides.
Mirages • Light refracted from a far away source looks closer
Mirages
Sunsets & Rises • Sunlight is refracted as it strikes the atmosphere at great angles bending light towards Earth
Sunsets • Because different wavelengths are refracted differently, colors change
Sunsets
Rainbows • Sunlight is refracted & reflected by rain droplets dispersing the light into a spectrum
Rainbows
Rainbows fall o from 40 – 42 from incident
Rainbows fall o from 40 – 42 from incident
A light ray from water (nw = 1. 33) & strikes diamond (ndiamd = 2. 42) with an incident angle o of 53. 0. Calculate the angle of refraction:
Answer the questions at the end of Chapter 16
Answer the questions at the end of Chapter 17
A light ray from water (nw = 1. 33) & strikes glass (nglass = 1. 51) with an incident angle of o 53. 0. Calculate the angle of refraction:
Calculate the angle of total internal reflection of pukon with n = 3. 00
An incident ray from air strikes quartz (n = 1. 50) at an angle of o 30 from normal. Calculate: refl & refr
- Reflection refraction transmission and absorption of light
- Why can we represent light rays using a ruler
- Rainbow total internal reflection
- Chapter 29 reflection and refraction
- Light light light chapter 23
- Into the light chapter 22
- Light light light chapter 22
- Reflection vs refraction
- Reflection refraction diffraction interference
- Refraction vs diffraction
- Blue relfection ray
- Poem about reflection and refraction
- Refraction examples
- Bill nye light and optics
- What is invictus
- Bill nye reflection and refraction
- Reflection refraction
- Reflection and refraction venn diagram
- Venn diagram of climate and weather
- Lighthe
- Reflection and refraction learning task 1
- Which materials let light through
- The visual response of the eye to reflected rays of light
- Total internal reflection in diamond
- Concave vs convex light refraction
- Refraction of light in lenses
- Learning objectives of refraction of light
- Phenomena related to refraction
- Refraction of light
- When a wave reaches a boundary it
- Refraction of light
- Snell's law formula
- Noise and light discipline
- Meniscus lens ray diagram
- Explain reflection
- Reflection light analogy
- Light strikes
- Light reflection
- Plane mirror used
- Reflection of light
- Reflection of light example
- Salt and light reflection
- Sigmaprc.in
- Light reflection experiment
- Concave mirrors can produce
- Characteristic of light
- Law of reflection of light
- Put out the light and then put out the light meaning
- Bacteria double membrane
- Or the bending of light and the bouncing off of light
- N-rays
- Origin of gamma rays