original momentum will be changed. The exact amount of the change pcannot be
predicted, but it will be of the same order of magnitude as the photon momentum
h. Hencep (3.23)The longer the wavelength of the observing photon, the smaller the uncertainty in the
electron’s momentum.
Because light is a wave phenomenon as well as a particle phenomenon, we cannot
expect to determine the electron’s location with perfect accuracy regardless of the in-
strument used. A reasonable estimate of the minimum uncertainty in the measurement
might be one photon wavelength, so thatx (3.24)The shorter the wavelength, the smaller the uncertainty in location. However, if we use
light of short wavelength to increase the accuracy of the position measurement, there will
be a corresponding decrease in the accuracy of the momentum measurement because
the higher photon momentum will disturb the electron’s motion to a greater extent. Light
of long wavelength will give a more accurate momentum but a less accurate position.
Combining Eqs. (3.23) and (3.24) givesx p h (3.25)This result is consistent with Eq. (3.22), x p 2.
Arguments like the preceding one, although superficially attractive, must be
approached with caution. The argument above implies that the electron can possess a
definite position and momentum at any instant and that it is the measurement process
that introduces the indeterminacy in x p. On the contrary, this indeterminacy is
inherent in the nature of a moving body. The justification for the many “derivations” of
this kind is first, they show it is impossible to imagine a way around the uncertainty
principle; and second, they present a view of the principle that can be appreciated in
a more familiar context than that of wave groups.3.9 APPLYING THE UNCERTAINTY PRINCIPLE
A useful tool, not just a negative statementPlanck’s constant his so small that the limitations imposed by the uncertainty princi-
ple are significant only in the realm of the atom. On such a scale, however, this principle
is of great help in understanding many phenomena. It is worth keeping in mind that
the lower limit of 2 for x pis rarely attained. More usually x p , or even
(as we just saw) x ph.Example 3.7
A typical atomic nucleus is about 5.0 10 ^15 m in radius. Use the uncertainty principle to
place a lower limit on the energy an electron must have if it is to be part of a nucleus.h
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