16.6 Postulate 5. Measurements and the Determination of the State of a System 721
PROBLEMS
Section 16.6: Postulate 5. Measurements and the
Determination of the State of a System
16.40a.Find〈E〉for the coordinate wave function
ψ(x)
√
1
3
ψ 0 +
√
1
3
ψ 1 +
√
1
3
ψ 2
whereψ 0 ,ψ 1 , andψ 2 are the three lowest-energy
harmonic oscillator energy eigenfunctions.
b.Show that the function is normalized.
c.FindσEfor the wave function in part a.
d.Tell what values would occur in a set of many
measurements ofE, given that the system is in the
state corresponding to the wave function of part a
immediately before each measurement. Give the
probability of each value.
16.41a.A measurement of the energy of a particle in a
three-dimensional cubic box gives a value
14 h^2 /(8ma^2 ). Tell what eigenfunctions are included in
the linear combination representation of the wave
function after the measurement.
b.How could the particle be put into a known state?
16.42The energy of a particle in a one-dimensional box of
lengthais measured repeatedly with the particle restored
to a specific but unknown state before each measurement.
The results are summarized as follows:
Value Probability
h^2 /(8ma^2 ) 0.25
4 h^2 /(8ma^2 ) 0.375
9 h^2 /(8ma^2 ) 0.125
16 h^2 /(8ma^2 ) 0.25
What can you say about the state prior to the
measurement?
Summary of the Chapter
In this chapter we have presented five postulates that are the theoretical basis of quantum
mechanics. The first two postulates establish a one-to-one correspondence between the
mechanical state of a system and a wave function and establish the time-dependent
Schrödinger equation, which governs the wave functions.
The third postulate asserts that there is a hermitian mathematical operator for each
mechanical variable. To write the operator for a given variable: (1) write the classical
expression for the variable in terms of Cartesian coordinates and momentum compo-
nents, (2) replace each momentum component by the relation
px
h ̄
i
∂
∂x
and its analogues.
The first part of the fourth postulate asserts that the only possible outcomes of a
measurement of a variable are the eigenvalues of the operator corresponding to that
variable. The second part of the fourth postulate asserts that the expectation value of
the variableAis given by
〈A〉
∫
Ψ∗ÂΨdq
∫
Ψ∗Ψdq
By study of the standard deviation ofA, given by
σA[〈A^2 〉−〈A〉^2 ]^1 /^2