728 17 The Electronic States of Atoms. I. The Hydrogen Atom
In previous chapters we used a capitalΨto represent a time-dependent wave function.
In the next few chapters we will useΨfor a time-independent wave function of two or
more particles.
Equation (17.1-16) can be solved by the separation of variables. We assume the trial
function:
Ψψc(xc,yc,zc)ψ(x,y,z) (17.1-17)
When the product function of Eq. (17.1-17) is substituted into Eq. (17.1-16) and the
variables are separated, we obtain the two equations
̂HcψcEcψc (17.1-18)
ĤrelψErelψ (17.1-19)
whereEcis the center-of-mass energy andErelis the relative energy and where
EEc+Erel (17.1-20)
Exercise 17.1
Carry out the steps to obtain Eqs. (17.1-18) to (17.1-20).
Equation (17.1-18) is the same as the Schrödinger equation for a free particle in three
dimensions, which we discussed in Chapter 15. Equation (17.1-19) is mathematically
equivalent to the Schrödinger equation for the motion of a particle of massμrelative
to a fixed origin (see Appendix E). Figure 17.2 depicts this equivalence. The vector
from the nucleus (labeledn) to the electron (labelede) in Figure 17.2a is equal to the
vector from the fixed origin to the fictitious particle of massμin Figure 17.2b. Since
the nucleus is much more massive than the electron the motion of the electron is nearly
the same as though the nucleus were stationary, and we will often refer to the relative
motion as electronic motion.
Particle of mass m
Vector of
lengthr
fromn to
Center of mass
Particle of mass mn
(a)(b)
Vector of
lengthr
from fixed
origin to
fictitious
particle of
mass
Fictitious particle of
mass
Fixed origin
e
e
meemn
memn
Figure 17.2 Figure to Illustrate the Equivalence between the Motion of a Particle of
Massμaround a Fixed Center and the Relative Motion of Two Particles.(a) The actual
two-particle system. (b) The fictitious particle of massμ.