16.5 The Uncertainty Principle of Heisenberg 713
Other measures of the uncertainty give a different minimum value. For a Gaussian
probability distribution, the uncertainty in a prediction at the 95% probability level is
equal to 1.96 times the standard deviation. At this level of uncertainty the right-hand
side of Eq. (16.5-2) would be replaced by a larger value.
The value of the uncertainty product depends on the system and on the state
considered. The uncertainty product for then1 state of the particle in a box, 0.09038h,
is slightly larger thanh/( 4 π), which equals 0.079577h. The uncertainty product for the
v0 state of the harmonic oscillator is exactly equal toh/( 4 π)and seems to be
the smallest uncertainty product for any system and any state. (See Problem 16.36.)
The uncertainty product for higher-energy states is larger.
Coordinates and momenta are not the only variables that have nonzero uncertainty
products. There is a general relation
∆A∆B≥
∣
∣
∣
∣
1
2
∫
ψ∗
[
Â,̂B
]
ψdq
∣
∣
∣
∣ (16.5-5)
where
[
Â,B̂
]
is the commutator of the operatorŝAandB̂.^4 From the commutator of
two angular momentum components, we can see that two components of the angular
momentum obey an uncertainty relation. (See Problem 16.16.)
Exercise 16.12
Use Eqs. (16.5-5) and (16.3-16) to obtain the same uncertainty relation forxandpxthat was
given in Eq. (16.5-2).
The uncertainty principle is a rather subtle concept, and deserves more discussion
than we give it in this book. However, the main idea is that it requires that the statistical
case applies to at least one of a conjugate pair of variables, and if the predictable case
applies to one of the variables, the other variable has an infinite uncertainty.
EXAMPLE16.22
Find〈px〉andσpxfor a free particle in a state corresponding to the wave function of
Eq. (15.3-28) withFset equal to zero.
Solution
We cancel the time-dependent factors to obtain
〈px〉
̄h
i
D∗D
∫
e−iκx
d
dx
eiκxdx
D∗D
∫
e−iκxeiκxdx
hκ ̄ hκ ̄
D∗D
∫
e−iκxeiκxdx
D∗D
∫
e−iκxeiκxdx
hκ ̄
∫
dx
∫
dx
We specify that the limits of the integrals are−LandL, with the intention of taking the limit
thatL→∞since all values ofxare possible. We cancel the integrals in the last quotient of
integrals prior to taking the limit, and obtain
〈px〉hκ ̄ (16.5-6)
(^4) Levine (Quantum Chemistry, 5th ed., Prentice-Hall, Englewood Cliffs, NJ, 2000, pp. 96, 206) assigns
the proof as a homework problem. A lot of hints are included, but it is a fairly long proof.