General Physics 2 Light as a Wave 1 The Nature of Light • When studying geometric optics, we used a ray model to describe the behavior of light. • A wave model of light is necessary to describe phenomena such as: • interference • diffraction • A particle model of light is necessary to describe phenomena observed in modern physics, for example, the interaction between light and atoms. We’ll get back to this later...
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General Physics 2Light as a Wave1 The Nature of Light When studying geometric optics, we used a ray model to describe the behavior of light. A wave model.
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General Physics 2 Light as a Wave 1
The Nature of Light
• When studying geometric optics, we used a ray model to describe the behavior of light.
• A wave model of light is necessary to describe phenomena such as:• interference• diffraction
• A particle model of light is necessary to describe phenomena observed in modern physics, for example, the interaction between light and atoms. We’ll get back to this later...
General Physics 2 Light as a Wave 2
Wave Nature of Light
• Christian Huygens (1629-1695)• contemporary of Newton • developed wave theory of light
• Huygen’s Principle• Every point on a wave front can
be considered as a source of tiny wavelets that spread out in the forward direction at the speed of the wave itself.
• The new wave front is the envelope of all the wavelets - tangent to all of them
General Physics 2 Light as a Wave 3
Huygen’s Principle
General Physics 2 Light as a Wave 4
Diffraction
• Huygen’s Principle is useful for understanding diffraction - the bending of waves behind obstacles into the shadow region
General Physics 2 Light as a Wave 5
Interference
• Thomas Young (1773-1829)• definitively (at least
temporarily) demonstrates wave nature of light
• Young’s Double-Slit Experiment• coherent light passes through 2
slits, S1 and S2
• light from S1 and S2 then interferes and pattern of dark and light spots is observed on the screen
General Physics 2 Light as a Wave 6
Interference
• Constructive interference occurs when• d sin = m , m = 0,1,2,...• m = order
• Destructive interference occurs when• d sin = (m + 1/2) , m = 0,1,2,...
• Source must be coherent • waves at S1 and S2 are in-phase
General Physics 2 Light as a Wave 7
what you see on the screen:
General Physics 2 Light as a Wave 8
Think-Pair-Share
• Monochromatic light falling on two slits 0.016 mm apart produces the fifth-order fringe at an 8.8 degree angle. What is the wavelength of the light used?
General Physics 2 Light as a Wave 9
Conceptual Question
• What happens to the interference pattern if the wavelength of light is increased from 500 nm to 700 nm?
• What happens instead if the wavelength stays at 500 nm but the slits are moved farther apart?
General Physics 2 Light as a Wave 10
Pair Problem
• Light of wavelength 680 nm falls on two slits and produces an interference pattern in which the fourth-order fringe is 38 mm from the central fringe on a screen 2.0 m away. What is the separation of the two slits?(Hint: tan = for small angles, and angles must be in radians!)
General Physics 2 Light as a Wave 11
Diffraction by a Disk
• Diffracted light interferes constructively at center of shadow• requires a point source of monochromatic light (e.g. laser)
General Physics 2 Light as a Wave 12
Diffraction by a Single Slit
• D sin = m • m = 1, 2, 3, ...
position of minima
for m=1, theta gives 1/2 width of central maximum
Motivation for making large diameter telescopes
General Physics 2 Light as a Wave 13
Diffraction Grating
• a large number of equally spaced parallel slits
• same relation as double-slit• d sin = m • m = 0, 1, 2, ...
• produces sharper and narrower interference patterns that double slit
General Physics 2 Light as a Wave 14
Diffraction Grating (L)
• double slit versus diffraction grating
• for multi-wavelength light
General Physics 2 Light as a Wave 15
Emission Tubes
• Look at several emission tubes using diffraction gratings & sketch spectrum
• Foundation of spectroscopy, a technique used in numerous scientific applications