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Transcript
Modern Physics 6a – Intro to
Quantum Mechanics
Physical Systems, Thursday 15 Feb. 2007, EJZ
Plan for our last four weeks:
• week 6 (today), Ch.6.1-3: Schrödinger Eqn in 1D,
square wells
• week 7, Ch.6.4-6: Expectation values, operators,
quantum harmonic oscillator, applications
• week 8, Ch.7.1-3: Schrödinger Eqn in 3D, Hydrogen
atom
• week 9, Ch.7.4-8: Spin and angular momentum,
applications
Outline – Intro to QM
• How to predict a system’s behavior?
• Schrödinger equation, energy & momentum operators
• Wavefunctions, probability, measurements
• Uncertainty principle, particle-wave duality
• Applications
How can we describe a system and
predict its evolution?
Classical mechanics:
Force completely describes a system:
Use F=ma = m dp/dt to find x(t) and v(t).
Quantum mechanics:
Wavefunction y completely
describes a QM system
Energy and momentum operators
E
hc

 pc
p
h

From deBroglie wavelength, construct a differential
operator for momentum:
h

2
k
2

h

2

p 
 k i
 
x
2
h
Similarly, from uncertainty principle, construct energy operator:
Et 

E i
t
Energy conservation  Schroedinger eqn.
E=T+V
Ey = Ty + Vy
where y is the wavefunction and
operators depend on x, t, and momentum:

p̂  i
x

E i
t
y
y
i

 Vy
2
t
2m x
2
2
Solve the Schroedinger eqn. to find the wavefunction, and
you know *everything* possible about your QM system.
Schrödinger Eqn
We saw that quantum mechanical systems can be
described by wave functions Ψ.
A general wave equation takes the form:
Ψ(x,t) = A[cos(kx-ωt) + i sin(kx-ωt)] = e i(kx-ωt)
Substitute this into the Schrodinger equation to see
if it satisfies energy conservation.
Derivation of Schrödinger Equation
i
Wave function and probability
Probability that a measurement of the system will
yield a result between x1 and x2 is x 2
2
 y ( x, t ) dx
x1
Measurement collapses the wave function
•This does not mean that the system was at X before the
measurement - it is not meaningful to say it was localized at
all before the measurement.
•Immediately after the measurement, the system is still at X.
•Time-dependent Schrödinger eqn describes evolution of y
after a measurement.
Exercises in probability: qualitative
Exercises in probability: quantitative
1. Probability that an individual selected at random has age=15?
 j N ( j )   j P( j )
2. Most probable age? 3. Median?
j 

N
j 0
4. Average = expectation value of repeated measurements of
many identically prepared system:
 j N ( j )   j P( j )
j 
N
5. Average of squares of ages =

2
2
j 0
6. Standard deviation s will give us uncertainty principle...
Exercises in probability: uncertainty
Standard deviation s can be found from the deviation from the
average: j  j  j
But the average deviation vanishes:
j  0
So calculate the average of the square of the deviation:
s 2   j 
Exercise: show that it is valid to calculate s more easily by:
s 2  j2  j
2
HW: Find these quantities for the exercise above.
2
Expectation values
Most likely outcome of a measurement of position, for a system
(or particle) in state y: 
x 
 x y ( x, t )
2
dx

Most likely outcome of a measurement of position, for a system
(or particle) in state y:
d x
p m
 i
dt

 * y
 y x

 dx

Uncertainty principle
Position is well-defined for a pulse with ill-defined
wavelength. Spread in position measurements = sx
Momentum is well-defined for a wave with precise . By its
nature, a wave is not localized in space. Spread in
momentum measurements = sp
We saw last week that
s xs p 

Particles and Waves
Light interferes and diffracts - but so do electrons! e.g. in Ni crystal
Electrons scatter like little billiard balls - but so does light! in
the photoelectric effect
Applications of Quantum mechanics
Blackbody radiation: resolve ultraviolet catastrophe, measure
star temperatures
Photoelectric effect: particle detectors and signal amplifiers
Bohr atom: predict and understand H-like spectra and energies
Structure and behavior of solids, including semiconductors
Scanning tunneling microscope
Zeeman effect: measure magnetic fields of stars from light
Electron spin: Pauli exclusion principle
Lasers, NMR, nuclear and particle physics, and much more...
Sign up for your Minilectures in Ch.7
Part 2: Stationary states and wells
• Stationary states
• Infinite square well
• Finite square well
• Next week: quantum harmonic oscillator
• Blackbody
Stationary states
2
Y ( x, t )
 2Y ( x, t )
i

 V ( x, t ) Y ( x , t )
2
t
2m x
If evolving wavefunction Y(x,t) = y(x) f(t)
can be separated, then the time-dependent term
satisfies
i
1 df
i
E
f dt
Everyone solve for f(t)=
Separable solutions are stationary states...
Separable solutions:
Y ( x, t )  y ( x )
(1) are stationary states, because
* probability density is independent of time [2.7]
* therefore, expectation values do not change
2
2
(2) have definite total energy, since the Hamiltonian is
sharply localized: [2.13]
s 2 0
H
(3) yi = eigenfunctions corresponding to each allowed
energy eigenvalue Ei.

 i En t
Y ( x, t )   cny n e
General solution to SE is [2.14]
n 1
Show that stationary states are separable:
Guess that SE has separable solutions Y(x,t) = y(x) f(t)
Y

t
2Y

2
x
sub into SE=Schrodinger Eqn
Divide by y(x) f(t) :
Y
i

t
2

Y
2
V Y
2
x
LHS(t) = RHS(x) = constant=E. Now solve each side:
You already found solution to LHS: f(t)=_________
 2 d 2y
 Vy  Ey
2
2m dx
RHS solution depends on the form of the potential V(x).
Now solve for y(x) for various V(x)
Strategy:
* draw a diagram
* write down boundary conditions (BC)
* think about what form of y(x) will fit the potential
* find the wavenumbers kn=2 /
* find the allowed energies En
* sub k into y(x) and normalize to find the amplitude A
* Now you know everything about a QM system in this
potential, and you can calculate for any expectation
value
Infinite square well:
V(0<x<L) = 0, V= outside
What is probability of finding particle outside?
2
Inside: SE becomes
d 2y
Ey  
2m dx 2
* Solve this simple diffeq, using E=p2/2m,
* y(x) =A sin kx + B cos kx: apply BC to find A and B
* Draw wavefunctions, find wavenumbers: kn L= n
* find the allowed energies:
(n ) 2
2
2
En 
,A 
2
* sub k into y(x) and normalize:
2mL
L
* Finally, the wavefunction is
2
n
y n ( x) 


sin 
x
L
 L 
Square well: homework
Repeat the process above, but center the infinite square
well of width L about the point x=0.
Preview: discuss similarities and differences
Infinite square well application:
Ex.6-2 Electron in a wire (p.256)
Finite square well: V=0 inside, V0 outside
Everywhere: Ψ, Ψ’, Ψ’’continuous
Outside: Ψ → 0, Ψ’’ ~ Ψ because E<V0 (bound)
Inside: Ψ’’ ~ - Ψ because V=0 (V-E < 0)
Which of these states are allowed?
Outside: Ψ → 0, Ψ’’ ~ Ψ because E<V0 (bound)
Inside: Ψ’’ ~ - Ψ because V=0 (V-E < 0)
Finite square well:
• BC: Ψ is NOT zero at the edges, so wavefunction can
spill out of potential
• Wide deep well has many, but finite, states
• Shallow, narrow well has at least one bound state
Summary:
• Time-independent Schrodinger equation
has stationary states y(x)
• k, y(x), and E depend on V(x) (shape & BC)
• wavefunctions oscillate as eiwt
• wavefunctions can spill out of potential
wells and tunnel through barriers