Physics 102: Lecture 23

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Physics 102: Lecture 23 De Broglie Waves & Compton Scattering Place exam revisions in box at front of room either now or at end of lecture Physics 102: Lecture 23, Slide 1

Exam 3 Monday April 21! Material covered Mirrors (Lect. 16) Resolution (Lect. 22) Fall 13 Exam Solutions Available Physics 102: Lecture 23, Slide 2

Early Indications of Problems with Classical Physics Blackbody radiation Photoelectric effect Wave-particle duality Lecture 22 Compton scattering DeBroglie waves Today Heisenberg Uncertainty Principle Next lecture Physics 102: Lecture 23, Slide 3

Is Light a Wave or a Particle? A) Wave B) Particle C) Yes Physics 102: Lecture 23, Slide 4

Quantum Physics and the Wave- Particle Duality I. Is Light a Wave or a Particle? Wave Electric and Magnetic fields act like waves Superposition: Interference and Diffraction Particle Photons (blackbody radiation) Collision with electrons in photo-electric effect BOTH Particle AND Wave Behavior Physics 102: Lecture 23, Slide 5

Are Electrons Particles or Waves? Particles, definitely particles. You can see them. You can bounce things off them. You can put them on an electroscope. How would know if electron was a wave? Look for interference! Physics 102: Lecture 22, Slide 6

Young s Double Slit w/ electron Jönsson 1961 d Source of monoenergetic electrons Physics 102: Lecture 22, Slide 7 2 slitsseparated by d L Screen a distance L from slits

Electrons are Waves? Electrons produce interference pattern just like light waves. Need electrons to go through both slits. What if we send 1 electron at a time? Does a single electron go through both slits? Physics 102: Lecture 22, Slide 8

Young s Double Slit w/ electron One electron at a time Merli 1974 Tonomura 1989 d Source of monoenergetic electrons L Interference pattern = probability Physics 102: Lecture 22, Slide 9 Same pattern for photons

ACT: Electrons are Particles Let s detect which hole an individual electron goes through. Does an electron pass through... A. Both Slits B. Only 1 Slit But now the interference is gone! Physics 102: Lecture 22, Slide 10

ACT: Electrons are Particles Let s detect which hole the electron goes through. Does the electron pass through... (1)Both Slits (2) Only 1 Slit But now the interference is gone! Physics 102: Lecture 22, Slide 11

Electrons are Particles and Waves! Depending on the experiment electron can behave like wave (interference) particle (localized mass and charge) If we don t look, electron goes through both slits. If we do look it chooses one. Physics 102: Lecture 22, Slide 12

Schrödinger's Cat http://www.youtube.com/watch?v=ioyychgwjq4 Physics 102: Lecture 22, Slide 13

Is Light a Wave or a Particle? Wave Electric and Magnetic fields act like waves Superposition, Interference, and Diffraction Particle Photons Collision with electrons in photo-electric effect Compton scattering from electrons Shows that photons (massless particles) have momentum! Reminder: for massive particles, p = mv so how can a photon have momentum? BOTH Particle AND Wave Behavior Physics 102: Lecture 23, Slide 14

Compton Scattering This experiment really shows photon momentum! P incoming photon + 0 = P outgoing photon + P electron Incoming photon has momentum p, and wavelength Photon energy E hf hc Electron at rest Photon momentum p h Experiment: Outgoing photon has longer wavelength Recoil electron carries some momentum and KE E = pc Physics 102: Lecture 23, Slide 15

Compton Scattering Incident photon loses momentum, since it transfers momentum to the electron Lower momentum means longer wavelength This is proof that a photon has momentum p h Physics 102: Lecture 23, Slide 16

De Broglie Waves p h h p So far only photons have wavelength, but De Broglie postulated that it holds for any object with momentum: an electron, a nucleus, an atom, a baseball,... Explains why we can see interference and diffraction for material particles like electrons!! Physics 102: Lecture 23, Slide 18

Checkpoint 2 Which baseball has the longest De Broglie wavelength? 23% 65% 12% (1) A fastball (100 mph) (2) A knuckleball (60 mph) (3) Neither - only curveballs have a wavelength Lower momentum gives higher wavelength. p = mv, so slower ball has smaller p. h p Physics 102: Lecture 23, Slide 19

DeBroglie waves for massive objects are small! Baseball: m=0.5 kg Fastball: v=100 mph=45 m/s =h/mv=3 10 35 m Remember: single-slit diffraction sinθ = λ/w Imagine slit is an atom, w = 10 10 m θ = 2 10 23 degrees Physics 102: Lecture 23, Slide 20 This is one reason we don t observe macroscopic interference!

ACT: De Broglie Wavelength A stone is dropped from the top of a building. What happens to the de Broglie wavelength of the stone as it falls? A. It decreases B. It stays the same C. It increases Speed, v, KE=mv 2 /2, and momentum, p=mv, increase. p h h p Physics 102: Lecture 23, Slide 21

Some Numerology Standard units (m, kg, s) are not convenient for talking about photons & electrons 1 ev = energy gained by a charge +e when accelerated through a potential difference of 1 Volt e = 1.6 x 10-19 C so 1 ev = 1.6 x 10-19 J h = 6.626 x 10-34 J sec c = 3 x 10 8 m/s hc = 1.988 x 10-25 J m = 1240 ev nm mass of electron m = 9.1 x 10-31 kg mc 2 = 8.2 x 10-13 J = 511,000 ev = 511 kev Physics 102: Lecture 23, Slide 22

Equations are different - be careful! Photon with 1 ev energy: Comparison: Wavelength of Photon vs. Electron You have a photon and an electron, both with 1 ev of energy. Find the de Broglie wavelength of each. E hc hc E 1240 ev nm 1eV 1240 nm Electron with 1 ev kinetic energy: KE 1 2 mv 2 and p = mv, so KE = p2 2m Solve for p 2m(K.E.) h 2m(KE) Physics 102: Lecture 23, Slide 23 hc 2 2mc (KE) 1240 ev nm 2(511,000 ev)(1ev) Big difference! 1.23nm

X-ray vs. electron diffraction X-ray diffraction e diffraction Demo Identical pattern emerges if de Broglie wavelength of e equals the X-ray wavelength! Physics 102: Lecture 23, Slide 24 From College Physics, Vol. Two

Checkpoints 3.1, 3.2 Photon A has twice as much momentum as Photon B. Compare their energies. 20% 60% 20% A E A = E B B E A = 2 E B C E A = 4 E B Electron A has twice as much momentum as Electron B. Compare their energies. 20% 30% 50% A. E A = E B B. E A = 2 E B C. E A = 4 E B Physics 102: Lecture 23, Slide 25 E hc KE 1 2 h p and so cp mv 2 E double p then double E 2 p 2m double p then quadruple E

ACT: De Broglie Compare the wavelength of a bowling ball with the wavelength of a golf ball, if each has 10 Joules of kinetic energy. A) bowling > golf B) bowling = golf C) bowling < golf h 2m( KE) Physics 102: Lecture 23, Slide 26 h p

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