The Chemistry Maths Book, Second Edition

28 Chapter 1Numbers, variables, and units

In this form the equation is often referred to as the ‘Schrödinger equation in atomic

units’. The results of computations are then numbers that must be reinterpreted

as physical quantities. For example, the quantity Ein equation (1.18) is an energy.

Solution of equation (1.19) gives the numbersE 1 = 1 − 122 n

2

, for all positive integers n,

and these numbers are then interpreted as the energiesE 1 = 1 − 122 n

2

E

h

.

EXAMPLE 1.21The atomic unit of energy

By Coulomb’s law, the potential energy of interaction of chargesq

1

andq

2

separated

by distance ris

whereε

0

1 = 1 8.85419 1 × 110

− 12

F m

− 1

is the permittivity of a vacuum. For chargesq

1

1 = 1 Z

1

e

andq

2

1 = 1 Z

2

eseparated by distancer 1 = 1 Ra

0

,

(i) To show that the unit is the hartree unitE

h

in Table 1.4, usea

0

1 = 14 πε

0

A

2

2 m

e

e

2

:

(ii) To calculate the value of E

h

in SI units, use the values of eand a

0

given in

Table 1.4. Then

= 1 (4.35975 1 × 110

− 3

) 1 × 1 (10

− 15

) 1 × 1 (C

2

1 F

− 1

)

From the definitions of the coulomb C and farad F in Table 1.2,F 1 = 1 C

2

1 J

− 1

so that

C

2

1 F

− 1

1 = 1 J. Therefore

0 Exercise 108

e

a

E

2

00

18

4

10

πε

=×=

−

4.35975 J

h

e

a

2

00

2

4

1 60218

πε 4 3 14159 8 85419 5 29177

=

×××



.

...















×

×

×

















×

−−

−−

10 10

10 10

19 19

12 11

2

C

F m m

−

















1

e

a

e

me

2

00

2

0

0

2

2

44

4

ππ

π

εε

ε

=

















÷

















=



e

ee

me me

2

0

2

0

2

4

2

4

416

π

ππ

ε

ε

















×

















=

ee

 εε

0

22



=E

h

V

ZZ

R

e

a

=

































12

2

00

4 πε

V

qq

r

=

12

0

4 πε