Radioactivity Integrated Science Chapter 25 Notes Chapter 25 Notes.
Chapter 25
description
Transcript of Chapter 25
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Chapter 25
Waves and Particles
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Wave Phenomena
• Interference• Diffraction• Reflection
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l – wavelength: distance between crests (meters)T – period: the time between crests passing fixed location (seconds)v – speed: the distance one crest moves in a second (m/s)f – frequency: the number of crests passing fixed location in one second (1/s or Hz) – angular frequency: 2f: (rad/s)
Tv l
Tf 1
fv l
Wave Description
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E E0 cos t E0 cos2T
t
Wave: Variation in Time
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xExEE
l
l 2cos2cos 00
Wave: Variation in Space
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xEE
l2cos0
t
TEE 2cos0
xt
TEE
l 22cos0
‘-’ sign: the point on wave moves to the right
Wave: Variation in Time and Space
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xt
TEE
l 22cos0
But E @ t=0 and x =0, may not equal E0
l xt
TEE 22cos0
phase shift, =0…2
Two waves are ‘out of phase’
Wave: Phase Shift
tEt
TEE cos2cos 00
(Shown for x=0)
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tEE cos0
E0 is a parameter called amplitude (positive). Time dependenceis in cosine function
Often we detect ‘intensity’, or energy flux ~ E2. For example: Vision – we don’t see individual oscillations
Intensity I (W/m2):20EI
Works also for other waves,such as sound or water waves.
Wave: Amplitude and Intensity
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Superposition principle: The net electric field at any location isvector sum of the electric fields contributed by all sources.
Can particle model explain the pattern?
Laser: source of radiation which has the same frequency (monochromatic) and phase (coherent) across the beam.
Two slits are sources of two waves with the same phase and frequency.
Interference
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Two emitters:
E1
E2
Fields in crossing point
tEE
tEE
coscos
02
01
Superposition: tEEEE cos2 021
Amplitude increases twice: constructive interference
Interference: Constructive
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Two emitters:
E1
E2
tEEEE cos2 021
What about the intensity (energy flux)?
Energy flux increases 4 times while two emitters produce onlytwice more energy
There must be an area in space where intensity is smaller than thatproduced by one emitter
Interference: Energy
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E1
E2
ttEEEE coscos021
tEEtEE
coscos
02
01
tcos
0
Two waves are 1800 out of phase: destructive interference
Interference: Destructive
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Superposition principle: The net electric field at any location isthe vector sum of the electric fields contributed by all sources.
Interference
tEE
tEE
coscos
02
01
tEEEE cos2 021
Amplitude increases twice
Constructive: Energy flux increases 4 times while two emitters produce only twice more energy
ttEEEE coscos021
tEEtEE
coscos
02
01
Two waves are 1800 out of phase
Constructive: Destructive:
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Intensity at each location depends on phase shift between twowaves, energy flux is redistributed.
Maxima with twice the amplitude occur when phase shift between two waves is 0, 2, 4, 6 …(Or path difference is 0, l, 2 l…)
Minima with zero amplitude occur when phase shift between two waves is , 3, 5 …(Or path difference is 0, l/2, 3l/2…)
Can we observe complete destructive interference if 1 2 ?
Interference
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Predicting Pattern For Two SourcesPoint C on screen is very far from sourcesC
normal
Need to know phase difference
Very far: angle ACB is very small
Path AC and BC are equal
Path difference: )sin(dl
If l = 0, l, 2l, 3l, 4l … - maximumIf l = l/2, 3l/2, 5l/2 … - minimum
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Predicting Pattern For Two SourcesC
normal
Path difference: )sin(dl
If l = 0, l, 2l, 3l, 4l … - maximumIf l = l/2, 3l/2, 5l/2 … - minimum
What if d < l ?
complete constructive interferenceonly at =00, 1800
What if d < l/2 ?
no complete destructive interference anywhere
Note: largest l for =/2
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d = 4.5 l
Why is intensity maximum at =0 and 1800 ?
Why is intensity zero at =90 and -900 ?
What is the phase difference at Max3?
Intensity versus AnglePath difference: )sin(dl
If l = 0, l, 2l, 3l, 4l … - maximumIf l = l/2, 3l/2, 5l/2 … - minimum
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Path difference: )sin(dl
If l = 0, l, 2l, 3l, 4l … - maximumIf l = l/2, 3l/2, 5l/2 … - minimum
d = l/3.5
Two sources are l/3.5 apart. What will be the intensity pattern?
Intensity versus Angle
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Path difference:
If l = 0, l, 2l, 3l, 4l … - maximumIf l = l/2, 3l/2, 5l/2 … - minimum
)sin(dl
L=2 m, d=0.5 mm, x=2.4 mmWhat is the wavelength of this laser?
)sin(l ddl )sin(
Lx
)tan(
Small angle limit: sin() tan()
Lx
d
lnm m 600106 7
Lxdl
Two-Slit Interference
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Using interference effect we can measure distances with submicronprecision
laser
Detector
Application: Interferometry
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Coherent beam of X-rays can be used to reveal the structure of a crystal.Why X-rays?
- they can penetrate deep into matter- the wavelength is comparable to interatomic distance
Diffraction = multi-source interference
Multi-Source Interference: X-ray Diffraction
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Diffraction = multi-source interference
lattice
X-ray
Electrons in atoms will oscillate causing secondary radiation.Secondary radiation from atoms will interfere.Picture is complex: we have 3-D grid of sources
We will consider only simple cases
Multi-Source Interference
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Acceleratedelectrons
Copper
X-rays
Electrons knock out innerelectrons in Cu. When theseelectrons fall back X-rayis emitted.(Medical equipment)
Synchrotron radiation: Electrons circle around accelerator.Constant acceleration leads to radiation
Generating X-Rays
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Simple crystal: 3D cubic grid
first layer
Simple case: ‘reflection’ incident angle = reflected anglephase shift = 0
X-Ray: Constructive Interference
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Reflection from the second layer will not necessarily be in phase
Path difference:
sin2dl
Each layer re-radiates. The total intensity of reflected beam depends on phase difference between waves ‘reflected’ from different layers
Condition for intense X-ray reflection:
where n is an integer l nd sin2
X-Ray: Constructive Interference
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crystalturn crystal
x-ray diffracted
l nd sin2
May need to observe several maxima to find n and deduce d
Simple X-Ray Experiment
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X-ray of Tungsten
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Suppose you have a source of X-rays which has a continuum spectrum of wavelengths.How can one make it monochromatic?
crystal
incident broadband X-ray
reflected single-wavelength X-ray
l nd sin2
Using Crystal as Monochromator
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Powder contains crystals in all possible orientations
polycrystalline LiF
Note: Incident angle doesn't have to be equal to scattering angle.Crystal may have more than one kind of atoms.Crystal may have many ‘lattices’ with different d
X-Ray of Powdered Crystals
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(Myoglobin) 1960, Perutz & Kendrew
X-Ray of Complex Crystals
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Why do we see reflection of lightfrom any smooth surface?
Condition for intense X-ray reflection:
where n is an integer l nd sin2
Visible light:l ~ 6000 Å >> interatomic spacing
Reflection from many layers is almostin-phase
Reflection of Visible Light
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Constructive interference:The only possible differencein path length is zero.
There will be maxima onlywhen incident angle is equalto scattering angle.
Reflection of Visible Light
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Thin films such as soap bubbles are often colored: interference
Consider thin l/2-thick filmThere are ~3000 atomic layers
Layer 1 and (N/2+1): destructive interference
For each layer i=1…N/2 there is a layer i+N/2 which re-radiates with 1800 phase shift resulting in zero intensity – there will be no reflection of light for this particular wavelength
Thin-Film Interference
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Destructive interference: for film thickness nl/2.
Constructive interference: for film thickness l/4, 3l/4, 5l/4…
Why are soap bubbles so colorful?
Why after a while soap bubbles lose their color?
Why there is no such effect for thick glass plates?
Other examples or thin-film interference:oil or gasoline on waterbutterfly wings (in some cases)bird feathers (in some cases)
Thin-Film Interference
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Wavelength of light in dense materials is shorter than in vacuum.
Atoms get polarized due to the E induced by EM wave and due to the field created by other polarized atoms.
The crest-to-crest distance in the net electric field is reduced
v=lf since l is reduced, the speed v is slower
Index of refraction: n=c/v, or v=c/n
Index of Refraction
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Index of refraction: n=c/v, or v=c/n
Water: n=1.33Glass: n~1.5
Frequency of light: not affected
v=lf Wavelength: l’ = l/n
l1 = l/n1
l2 = l/n2
l1 n1= l2 n2
X-rays: very high frequency, barely polarize atoms, speed almost not affected
Index of Refraction