Physical Chemistry Third Edition

(C. Jardin) #1

17.2 The Relative Schrödinger Equation. Angular Momentum 729


EXAMPLE17.1

The electron mass is 9. 10939 × 10 −^31 kg and the proton mass is 1. 672623 × 10 −^27 kg.
Calculate the ratio of the reduced mass of the hydrogen atom to the mass of the electron.
Solution

μ

memp
me(me+mp)


(1. 672623 × 10 −^27 kg)(9. 10939 × 10 −^31 kg)
1. 672623 × 10 −^27 kg+ 9. 10939 × 10 −^31 kg

 9. 10443 × 10 −^31 kg
μ
me

9. 10443 × 10 −^31 kg
9. 10939 × 10 −^31 kg

 0. 99946

PROBLEMS


Section 17.1: The Hydrogen Atom and the Central Force
System


17.1 The electron mass is 9. 10939 × 10 −^31 kg and the proton
mass is 1. 672623 × 10 −^27 kg. For a hydrogen atom with
the electron at a distance 1. 000 × 10 −^10 m from the
nucleus, find the distance from the center of mass to the
nucleus and to the electron. The calculation is easier if you
assume that the particles are temporarily on thexaxis with
the nucleus at the origin.


17.2 The mass of the earth is 5. 98 × 1024 kg and the mass of
the sun is 1. 99 × 1030 kg. Find the reduced mass of the
earth and the sun and express it as a percentage of the mass
of the earth.


17.3 The mass of the earth is 5. 98 × 1024 kg and the mass of
the sun is 1. 99 × 1030 kg. Assume that the earth is
1. 4957 × 108 km from the sun and find the distance from
the center of the sun to the center of mass of the earth and
the sun.
17.4 a.The mass of the moon is 7. 34 × 1022 kg and the mass
of the earth is 5. 98 × 1024 kg. Assume that the moon is
3. 818 × 105 km from the earth and find the distance
from the center of the earth to the center of mass of the
moon and the earth.
b.Find the reduced mass of the moon and the earth and
express it as a percentage of the mass of the
moon.

17.2 The Relative Schrödinger Equation.

Angular Momentum


The relative Schrödinger equation cannot be solved in Cartesian coordinates. We trans-
form to spherical polar coordinates in order to have an expression for the potential
energy that contains only one coordinate. Spherical polar coordinates are depicted in
Figure 17.3. The expression for the Laplacian operator in spherical polar coordinates
is found in Eq. (B-47) of Appendix B. The relative Schrödinger equation is now

Ĥrelψ−h ̄

2
2 μr^2

[


∂r

(

r^2

∂ψ
∂r

)

+

1

sin(θ)


∂θ

(

sin(θ)

∂ψ
∂θ

)

+

1

sin^2 (θ)

∂^2 ψ
∂φ^2

]

+V(r)ψ

Erelψ (17.2-1)
Free download pdf