xis|f(x)|^2 dx. The probability for a particle to have wave number in regiondkaround some value
ofkis|A(k)|^2 dk. (Remember thatp= ̄hkso the momentum distribution is very closely related. We
work withkfor a while for economy of notation.)
5.2 Two Examples of Localized Wave Packets
Lets now trytwo examples of a wave packet localized inkand properly normalized att= 0.
- A “square” packet:A(k) =√^1 afork 0 −a 2 < k < k 0 +a 2 and 0 elsewhere.
- A Gaussian packet:A(k) =
( 2 α
π) 1 / 4
e−α(k−k^0 )
2
.These are both localized in momentum aboutp= ̄hk 0.
Check the normalization of (1).
∫∞−∞|A(k)|^2 dk=1
ak∫ 0 +a 2k 0 −a 2dk=1
aa= 1Check the normalization of (2) using the result for a definite integral of a Gaussian (See section
5.6.3)
∞∫
−∞dx e−ax2
=√π
a.∫∞−∞|A(k)|^2 dk=√
2 α
π∫∞
−∞e−^2 α(k−k^0 )2
dk=√
2 α
π√
π
2 α= 1
So now we take the Fourier Transform of (1) right here.
f(x) =1
√
2 π∫∞
−∞A(k)eikxdk=1
√
2 π1
√
ak∫ 0 +a 2k 0 −a 2eikxdkf(x) =1
√
2 πa1
ix[
eikx]k 0 +a 2
k 0 −a 2 =1
√
2 πa1
ixeik^0 x[
eiax/^2 −e−iax/^2]
f(x) =1
√
2 πa1
ixeik^0 x[
2 isin(ax
2)]
=
√
a
2 πeik^0 x2 sin(ax
2)
axNote that
2 sin(ax 2 )
ax is equal to 1 atx= 0 and that it decreases from there. If you square this,
it should remind you of a single slit diffraction pattern! In fact, the single slit gives us a square
localization in position space and the F.T. is thissin(xx)function.
The Fourier Transform of a Gaussian (See section 5.6.4) wave packetA(k) =
( 2 α
π) 1 / 4
e−α(k−k^0 )2
isf(x) =(
1
2 πα) 1 / 4
eik^0 xe−
x 42 α