750 17 The Electronic States of Atoms. I. The Hydrogen Atom
z
y
x
Volume element of
volumer^2 sin()dddr
dr
rsin()d
rsin()d
rsin()
r d
r
d
Figure 17.10 The Volume Element in Spherical Polar Coordinates.
In spherical polar coordinates,
∫∞
0
∫π
0
∫ 2 π
0
ψ(r,θ,φ)|^2 r^2 sin(θ)dφdθdr
∫∞
0
∫π
0
∫ 2 π
0
|ψ(r,θ,φ)|^2 d^3 r1 (17.5-4)
where
d^3 rr^2 sin(θ)dφdθdr (spherical polar coordinates) (17.5-5)
The factorr^2 sin(θ), which is called aJacobian, is required to complete the element
of volume in spherical polar coordinates. The form of this Jacobian can be deduced
from the fact that an infinitesimal length in therdirection isdr, an infinitesimal arc
length in theθdirection isrdθ, and an infinitesimal arc length in theφdirection is
rsin(θ),dφif the angles are measured in radians. The element of volume is the product
of these mutually perpendicular infinitesimal lengths. Spherical polar coordinates were
depicted in Figure 17.3. The volume element is crudely depicted by finite increments
in Figure 17.10.
The Jacobian is named for Carl Gustav
Jacob Jacobi, 1804–1851, a great
German mathematician who made
numerous contributions to mathematics.
The normalization integral for the hydrogen atom orbitals can be factored in spherical
polar coordinates:
∫∞
0
R∗Rr^2 dr
∫π
0
Θ∗Θsin(θ)dθ
∫ 2 π
0
Φ∗Φdφ 1 (17.5-6)
We make the additional normalization requirement that each of the three integrals in
this equation equals unity. The constants in the formulas for the R,Θ, andΦfactors
that we have introduced correspond to this requirement. These separate normalizations
in Eq. (17.5-6) simplify the calculation of many expectation values.
EXAMPLE17.7
Calculate the expectation values〈 1 /r〉and〈V〉for a hydrogen-like atom in the 1sstate.