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Transcript
Phys 102 – Lecture 24
The classical and Bohr atom
1
State of late
th
19
Century Physics
• Two great theories
“Classical physics”
Newton’s laws of mechanics & gravity
Maxwell’s theory of electricity & magnetism, including
EM waves
• But... some unsettling problems
Stability of atom & atomic spectra
Photoelectric effect
...and others
• New theory required
Quantum mechanics
Phys. 102, Lecture 24, Slide 2
Stability of classical atom
Prediction – orbiting e– is an oscillating charge & should emit
EM waves in every direction
Recall Lect. 15 & 16
+
utot
–
1
1 2
2
 ε0 Erms 
Brms
2
2 μ0
EM waves carry energy, so e– should lose energy & fall into
nucleus!
Classical atom is NOT stable!
Lifetime of classical atom = 10–11 s
Reality – Atoms are stable
Phys. 102, Lecture 24, Slide 3
Atomic spectrum
Prediction – e– should emit light at whatever frequency f it
orbits nucleus
d sin θ  mλ
Discharge tube
Recall Lecture 22
Diffraction grating
Screen
Hydrogen
Reality – Only certain
frequencies of light are
emitted & are different
for different elements
Helium
Nitrogen
Oxygen
Phys. 102, Lecture 24, Slide 4
Frequency
Quantum mechanics
Quantum mechanics explains stability of atom & atomic
spectra (and many other phenomena...)
QM is one of most successful and accurate scientific theories
Predicts measurements to <10–8 (ten parts per billion!)
Wave-particle duality – matter behaves as a wave
Particles can be in many places at the same time
Processes are probabilistic not deterministic
Measurement changes behavior
Certain quantities (ex: energy) are quantized
Phys. 102, Lecture 24, Slide 5
Matter waves
Matter behaves as a wave with de Broglie wavelength
Planck’s constant
Wavelength of
matter wave
h  6.626 1034 J  s
h
λ
p
Momentum
mv of particle
Ex: a fastball (m = 0.5 kg, v = 100 mph ≈ 45 m/s)
λ fastball
h 6.626 1034


 3 1035 m
0.5  45
p
20 orders of magnitude
smaller than the proton!
Ex: an electron (m = 9.1×10–31 kg, v = 6×105 m/s)
h
6.626 1034
 1.2 nm
X-ray wavelength
λelectron  
31
5
p 9.1110  6 10
How could we detect matter wave?
Interference!
Phys. 102, Lecture 24, Slide 6
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!
Phys. 102, Lecture 24, Slide 7
Electron diffraction
Beam of mono-energetic e– passes through double slit
Interference pattern =
probability
d sin θ  mλ
h
λ
p
– –
–
– ––
Wait! Does this mean e–
passes through both slits?
What if we measure which
slit the e– passes through?
Merli – 1974
Tonomura – 1989
Phys. 102, Lecture 24, Slide 8
ACT: Double slit interference
Consider the interference pattern from a beam of monoenergetic electrons A passing through a double slit.
Now a beam of electrons B with 4x
the energy of A enters the slits.
What happens to the spacing Δy
between interference maxima?
A.
B.
C.
D.
E.
Δy
L
ΔyB = 4 ΔyA
ΔyB = 2 ΔyA
ΔyB = ΔyA
ΔyB = ΔyA / 2
ΔyB = ΔyA / 4
Phys. 102, Lecture 24, Slide 9
The “classical” atom
Negatively charged electron orbits around positively charged
nucleus
–
Orbiting e has centripetal acceleration:
e 2 mv 2
FE  k 2 
r
r
Total energy of electron:
r
+
ke 2
so,
 mv 2
r
FE
Etot
–
1 2
e2
1 ke2

 K  U  mv  k
2
r
2 r
Etot
v
0
r
Hydrogen atom
Recall Lect. 4
Phys. 102, Lecture 24, Slide 10
The Bohr model
e– behave as waves & only orbits that fit an integer number
of wavelengths are allowed
Orbit circumference
2πr  nλ
n  1, 2,3
+
Angular momentum is quantized
Ln  n

h
2π
“h bar”
Phys. 102, Lecture 24, Slide 11
ACT: Bohr model
What is the quantum number n of this hydrogen atom?
+
A.
B.
C.
D.
n=1
n=3
n=6
n = 12
Phys. 102, Lecture 24, Slide 12
Energy and orbit quantization
Angular momentum is quantized
Ln  pr  mvr  n
+
n=1
n  1, 2,3
E
n=2
n=3
Free electron
r
n=4
n=3
n=2
Radius of orbit is quantized
n2 2
2

n
a0
rn 
2
mke
Energy is quantized
Smallest orbit
has energy –E1
“ground state”
1 ke 2
E
En  
  21
2 rn
n
“Bohr radius”
n=1
Phys. 102, Lecture 24, Slide 13
ACT: CheckPoint 3.2
Suppose the charge of the nucleus is doubled (+2e), but
the e– charge remains the same (–e). How does r for the
ground state (n = 1) orbit compare to that in hydrogen?
n2 2
For hydrogen: rn 
mke2
+2e
A. 1/2 as large
B. 1/4 as large
+
–
C. the same
Phys. 102, Lecture 24, Slide 14
ACT: CheckPoint 3.3
There is a particle in nature called a muon, which has the
same charge as the electron but is 207 times heavier. A muon
can form a hydrogen-like atom by binding to a proton.
How does the radius of the ground state (n = 1) orbit for
this hydrogen-like atom compare to that in hydrogen?
A. 207× larger
B. The same
C. 207× smaller
Phys. 102, Lecture 24, Slide 15
Atomic units
At atomic scales, Joules, meters, kg, etc. are not convenient units
“Electron Volt” – energy gained by charge +1e when accelerated
by 1 Volt: U  qV
1e = 1.610–19 C, so 1 eV = 1.610–19 J
Planck constant: h = 6.626  10–34 J∙s
Speed of light: c = 3  108 m/s
Electron mass: m = 9.1  10–31 kg
hc  2 1025 J  m  1240 eV  nm
mc 2  8.2 1013 J  511, 000 eV
ke2
Since U 
, ke2 has units of eV∙nm like hc
r
ke2
ke2
1
 2π

c
hc 137
ke2  1.44 eV  nm
“Fine structure constant” (dimensionless)
Phys. 102, Lecture 24, Slide 16
Calculation: energy & Bohr radius
Energy of electron in H-like atom (1 e–, nuclear charge +Ze):
2
Z
511, 000 eV Z 2
mk Z e
2  ke 
  2 mc 
En  
 
2 2
2n
2 137 2 n 2
2n
 c
Z2
 13.6 eV 2
n
2
2 4
2
2
Radius of electron orbit:
n2 c  c  n 2 1240 eV  nm
n2
n2 2


137
rn  a0 
2 
2 
2
Z mc  ke 
Z 2π  511, 000 eV
Z
mkZe
n2
 0.0529nm
Z
Phys. 102, Lecture 24, Slide 17
ACT: Hydrogen-like atoms
Consider an atom with a nuclear charge of +2e with a
single electron orbiting, in its ground state (n = 1), i.e. He+.
How much energy is required to ionize the atom totally?
A. 13.6 eV
B. 2 × 13.6 eV
C. 4 × 13.6 eV
Phys. 102, Lecture 24, Slide 18
Heisenberg Uncertainty Principle
e– beam with momentum p0 passes through slit will diffract
pf
Δy = a
–
Δpy
p0
p0
e– passed somewhere
inside slit.
Uncertainty in y
Momentum was along x, but
e– diffracts along y.
Uncertainty in y-momentum
If slit narrows, diffraction pattern spreads out
Uncertainty in y
Uncertainty in
y-momentum
y  p y 
2
Phys. 102, Lecture 23, Slide 19
ACT: CheckPoint 4
The Bohr model cannot be correct! To be consistent with
the Heisenberg Uncertainty Principle, which of the
following properties cannot be quantized?
1.
2.
3.
4.
En  
E1
n2
Energy is quantized
Angular momentum is quantized Ln  pn rn  n
Radius is quantized rn  n2a0
Linear momentum & velocity are quantized pn 
na0
A. All of the above
B. #1 & 2
C. #3 & 4
Phys. 102, Lecture 24, Slide 20
Summary of today’s lecture
• Classical model of atom
Predicts unstable atom & cannot explain atomic spectra
• Quantum mechanics
Matter behaves as waves
Heisenberg Uncertainty Principle
• Bohr model
Only orbits that fit n electron wavelengths are allowed
Explains the stability of the atom
Energy quantization correct for single e– atoms (H, He+, Li++)
However, it is fundamentally incorrect
Need complete quantum theory (Lect. 26)
Phys. 102, Lecture 23, Slide 21