16.4 Postulate 4 and Expectation Values 707
The predictable case is always identifiable by calculating the standard deviation of
the measurement. Here is an important fact:If a system is in a state corresponding
to an eigenfunction of the variable to be measured, the measurement belongs to the
predictable case.EXAMPLE16.18
For a particle in a one-dimensional box, find〈E〉andσEfor then1 stationary state.
SolutionσE[
〈E^2 〉−〈E〉^2] 1 / 2〈E〉∫
ψ∗ 1 Hψdx̂ ∫
ψ 1 ∗E 1 ψ 1 dxE∫
ψ 1 ∗ψ 1 dxE 1
h^2
8 ma^2
〈E^2 〉∫
ψ∗ 1 Ĥ^2 ψ 1 dx∫
ψ∗ 1 E 12 ψ 1 dxE^21∫
ψ 1 ∗ψ 1 dxE^21where we have used the fact thatĤ^2 ĤĤ. The standard deviation vanishes:σE(E^21 −E^21 )^1 /^2 0The outcome of the energy measurement is completely predictable if the particle is in this
stationary state, which corresponds to an energy eigenfunction.Exercise 16.10
a.For a general system whose wave functionψjis an eigenfunction of the operator̂Awith
eigenvalueaj, show that〈A〉ajand thatσA0.
b.For a one-dimensional harmonic oscillator, find〈E〉andσEfor the state corresponding to
thev1 energy eigenfunction.Wave Functions That Are Not Energy Eigenfunctions
The wave function of a system at a given instant can be any function that obeys
the proper boundary conditions. There is no requirement that it must obey the time-
independent Schrödinger equation. However, since the energy eigenfunctions are a
complete set, any wave function at a fixed time can be written as a linear combination
of energy eigenfunctions, as in Eqs. (15.3-20) and (16.3-35) withtset equal to zero.EXAMPLE16.19
For a one-dimensional harmonic oscillator, find〈E〉andσEif the state just prior to the
measurement corresponds to the normalized wave functionψ√
1
2
(ψ 0 +ψ 1 )whereψ 0 andψ 1 are the first two energy eigenfunctions, given in Eqs. (15.4-10) and (15.4-11).