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Light

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Title: Light


1
Light Reflection
2
Electromagnetic Waves
3
Fig. 21.22, p.675
4
The Electromagnetic Spectrum
Section 1 Characteristics of Light
Chapter 13
5
  • The most famous and conspicuous supernova
    remnant. The Crab Nebula is the centuries-old
    wreckage of a stellar explosion, or supernova,
    first noted by Chinese astronomers on July 4,
    1054, and that reached a peak magnitude of -6
    (about four times brighter than Venus). According
    to the Chinese records, it was visible in
    daylight for 23 days and in the night sky to the
    unaided eye for 653 days. Petroglyphs found in
    Navaho Canyon and White Mesa (both Arizona) and
    in the Chaco Canyon National Park (New Mexico)
    appear to be depictions of the event by Anasazi
    Indian artists. The Crab Nebula lies about
    6,300 light-years away in the constellation
    Taurus, measures roughly 10 light-years across,
    and is expanding at an average speed of 1,800
    km/s. Surprisingly, its expansion rate seems to
    be accelerating, driven by radiation from the
    central pulsar. Its luminosity at visible
    wavelengths exceeds 1,000 times that of the Sun

6
Crab NebulaX-ray image
Fig. 21.23a, p.676
7
Crab NebulaOptical image
Fig. 21.23b, p.676
8
Crab NebulaInfrared image
Fig. 21.23c, p.676
9
Crab NebulaRadio image
Fig. 21.23d, p.676
10
The Nature of Light
  • Light has dual natureParticles and Waves
  • Particles of light are called photons
  • Each photon has a particular energy
  • E h ƒ
  • h is Plancks constant
  • h 6.63 x 10-34 J s
  • Encompasses both natures of light
  • Interacts like a particle
  • Has a given frequency like a wave
  • c f ?

11
Geometric Optics Using a Ray Approximation
  • Light travels in a straight-line path in a
    homogeneous medium until it encounters a boundary
    between two different media
  • The ray approximation is used to represent beams
    of light
  • A ray of light is an imaginary line drawn along
    the direction of travel of the light beams

12
Ray Approximation
13
Electromagnetic Waves, continued
Chapter 13
  • Illuminance decreases as the square of the
    distance from the source.
  • The rate at which light is emitted from a source
    is called the luminous flux and is measured in
    lumens (lm).

14
Reflection of Light
  • A ray of light, the incident ray, travels in a
    medium
  • When it encounters a boundary with a second
    medium, part of the incident ray is reflected
    back into the first medium
  • This means it is directed backward into the first
    medium

15
Specular Reflection
  • Specular reflection is reflection from a smooth
    surface
  • The reflected rays are parallel to each other
  • All reflection in this text is assumed to be
    specular

16
Diffuse Reflection
  • Diffuse reflection is reflection from a rough
    surface
  • The reflected rays travel in a variety of
    directions
  • Diffuse reflection makes the road easy to see at
    night

17
Law of Reflection
  • The normal is a line perpendicular to the surface
  • It is at the point where the incident ray strikes
    the surface
  • ?i ?r

?
?i
?r
18
Image Formation by a Flat Mirror
Chapter 13
19
Refraction of Light
  • The incident ray, the reflected ray, the
    refracted ray, and the normal all lie on the same
    plane
  • The angle of refraction, ?2, depends on the
    properties of the medium

20
Concave Spherical Mirrors
Section 3 Curved Mirrors
Chapter 13
  • A concave spherical mirror is a mirror whose
    reflecting surface is a segment of the inside of
    a sphere.
  • Concave mirrors can be used to form real images.
  • A real image is an image formed when rays of
    light actually pass through a point on the image.
    Real images can be projected onto a screen.

21
Image Formation by a Concave Spherical Mirror
Chapter 13
Section 3 Curved Mirrors
22
Concave Spherical Mirrors, continued
  • The Mirror Equation relates object distance (p),
    image distance (q), and focal length (f ) of a
    spherical mirror.

23
Concave Spherical Mirrors,
Chapter 13
  • The Equation for Magnification relates image
    height or distance to object height or distance,
    respectively.

24
Sample Problem B
25
Mirrors Sign Conventions
  • p is the distance to the object
  • object in front of mirror
  • - object behind mirror
  • q is the distance to the image
  • - image behind mirror (virtual image)
  • image in front of mirror (real image)
  • f 1/2C 1/2R
  • for concave mirrors
  • - for convex mirrors
  • M image height/object height hi/ho -q/p
  • for upright image
  • - for inverted image
  • If Mlt1, the image is smaller than the object
  • If Mgt1, the image is larger than the object

26
Ray Diagram
  • Three rays can always be drawn for curved
    mirrors. Where they intersect is where the image
    is located.
  • Ray 1 A ray drawn from the object through the
    focal point is reflected parallel to the
    principal axis
  • Ray 2 A ray drawn from the object through the
    center of curvature is reflected back on itself.
  • Ray 3 A ray drawn from the object parallel to
    the principal axis reflects through the focal
    point.

27
Lens Imaging
Lens Type Object Beyond Focal Point Object At Focal Point Object Between Focal Point And Lens
Converging (convex) Real Inverted Reduced Image No Image Formed Erect Virtual Magnified Image
Diverging (concave) Virtual Erect Reduced Image Virtual Erect Reduced Image Virtual Erect Reduced Image
28
Sign Conventions for Thin Lenses
Quantity Positive When Negative When
Object location (p) Object is in front of the lens Object is in back of the lens
Image location (q) Image is in back of the lens Image is in front of the lens
Image height (h) Image is upright Image is inverted
R1 and R2 Center of curvature is in back of the lens Center of curvature is in front of the lens
Focal length (f) Converging lens Diverging lens
29
Ray Diagrams for Thin Lenses
  • Ray diagrams are essential for understanding the
    overall image formation
  • Three rays are drawn
  • The first ray is drawn parallel to the first
    principle axis and then passes through (or
    appears to come from) one of the focal lengths
  • The second ray is drawn through the center of the
    lens and continues in a straight line
  • The third ray is drawn from the other focal
    point and emerges from the lens parallel to the
    principle axis
  • There are an infinite number of rays, these are
    convenient

30
Fig. 22.16, p.697
31
Color
Chapter 13
  • Additive primary colors produce white light when
    combined.
  • Light of different colors can be produced by
    adding light consisting of the primary additive
    colors (red, green, and blue).

32
Color
  • Subtractive primary colors filter out all light
    when combined.
  • Pigments can be produced by combining subtractive
    colors (magenta, yellow, and cyan).

33
Polarization of Light Waves
  • Each atom produces a wave with its own
    orientation of E
  • All directions of the electric field E vector are
    equally possible and lie in a plane perpendicular
    to the direction of propagation
  • This is an unpolarized wave

34
Polarization of Light Waves
Chapter 13
  • Light can be polarized by reflection and
    scattering.
  • At a particular angle, reflected light is
    polarized horizontally.
  • The sunlight scattered by air molecules is
    polarized for an observer on Earths surface.

35
Polarization of Light, cont
  • A wave is said to be linearly polarized if the
    resultant electric field vibrates in the same
    direction at all times at a particular point
  • Polarization can be obtained from an unpolarized
    beam by
  • selective absorption
  • reflection
  • scattering

36
Aligned and Crossed Polarizing Filters
Chapter 13
Section 4 Color and Polarization
Crossed Filters
Aligned Filters
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