Descriptive Inorganic Chemistry, DIC, Fifth edition, 5 edition
Chapter 1 answers:

1 
Chapter 1 
 
THE ELECTRONIC STRUCTURE OF THE ATOM: A REVIEW 
 
Exercises 
1.2  (a) Region in space around a nucleus where the probability of finding an 
electron is high. 
(b) Orbital energy levels of the same energy. 
(c) When occupying orbitals of equal energy, it is energetically preferable 
for the electrons to adopt a parallel spin arrangement. 
 
1.4  5. 
 
1.6  6s. 
 
1.8  The quantum number l relates to the orbital shape. 
 
1.10  The pairing energy for the double occupancy of the 2s orbital is less than 
the energy separation of the 2s and 2p orbitals. 
 
1.12  (a) [Ar]4s2; (b) [Ar]4s13d5; (c) [Xe]6s24f145d106p2. 
 
1.14  (a) [Ar]; (b) [Ar]3d7; (c) [Ar]3d3. 
 
1.16  2+ and 4+.  Tin has a noble gas core ground-state electron configuration of 
[Kr]5s24d105p2.  The two 5p electrons are lost first, giving an ion of 2+ 
charge; the two 5s electrons are lost next, giving an ion of 4+ charge. 
 
1.18  4+.  Zirconium has a noble gas core ground-state electron configuration of 
[Ar]4s23d2.  Thus loss of both the two 4s electrons and the two 3d 
electrons will give a 4+ ion. 
 
2     Chapter 1  
1.20  (a) 3; (b) 2; (c) 4. 
 
 
1.22  (a) and (d). 
 
Beyond the Basics 
 
1.24  The Dirac wave equation was developed by the English physicist P. A. M. 
Dirac.  He applied the ideas of Einstein’s special theory of relativity to 
quantum mechanics.  Dirac’s model requires four quantum numbers, not 
the three of the Schrödinger model (where the spin quantum number is not 
part of the solution to the equation).  A fourth quantum number results 
from the special theory of relativity where events are defined by the three 
spatial coordinates plus a time coordinate. 
In the Dirac model, like the Schrödinger model, the principal 
quantum number, n, determines the size of an orbital.  The other quantum 
numbers have different meanings—the third and the fourth (instead of the 
second) determine the shape of the orbitals.  The shapes of the orbitals 
themselves differ from those using the Schrödinger equation, and there are 
no nodes.  This removes the conceptual problem of how an electron moves 
from one lobe of a p orbital to the other if there is a zero probability in 
between.  The answer is that the ―simplistic‖ Schrödinger equation is in 
error.  For high-atomic-number atoms, relativistic effects become of 
increasing importance and the Schrödinger equation becomes inadequate; 
the Dirac equation must be used. 
For a good introduction to the Dirac equation, see R. E. Powell, 
Relativistic Quantum Chemistry, J. Chem. Educ. 45 (1968): 558–563. 
 
1.26  Curium. [Rn]7s
2
5f
7
6d
1
. 
 
1.28  Of course, one can argue that orbitals are human constructs only! This 
question is a good topic for debate, but these authors veers toward the 
view that an orbital actually exists only when it is populated. Empty 
orbitals only potentially exist. 

1 
Chapter 1 
 
THE ELECTRONIC STRUCTURE OF THE ATOM: A REVIEW 
 
Exercises 
1.1  (a) Surface where the electron probability is zero. 
(b) No two electrons in an atom can have exactly the same set of quantum 
numbers. 
(c) Paramagnetic—the attraction into a magnetic field by an unpaired 
electron. 
 
1.3 
 
1.5  5p. 
 
1.7  The quantum number n relates to the size of an orbital. 
 
1.9  The two electrons paired and occupying the same orbital would be least 
favorable, because the pairing energy would be necessary to overcome the 
repulsive forces.  Paired but in different orbitals also comes with an 
energy cost because there is a finite probability that the electrons will 
occupy the same volume of space, again resulting in a repulsive energy 
factor.  With parallel spins there is zero probability that the electrons will 
occupy the same volume of space; hence this is the lowest energy 
condition. 
 
2     Chapter 1  
 
1.11  (a) [Ne]3s1; (b) [Ar]4s23d8; (c) [Ar]4s13d10. 
 
1.13  (a) [Ar]; (b) [Ar]; (c) [Ar]3d9. 
 
1.15  1+ and 3+.  Thallium has a noble gas core ground-state electron 
configuration of [Xe]6s24f145d106p1.  The 6p electron is lost first, 
giving an ion of 1+ charge; the two 6s electrons are lost next, giving an 
ion of 3+ charge and corresponding to the removal of all outer electrons: 
[Xe]4f145d10. 
 
1.17  1+.  Silver has a noble gas core ground state electron configuration of 
[Kr]5s14d10.  The 5s electron is lost first, giving an ion of 1+ charge and 
corresponding to the removal of all outer electrons: [Kr]4d10. 
 
1.19  (a) 2; (b) 0; (c) 4. 
 
 
 
1.21  Electron configuration of atom: [Rn]7s
2
5f
14
6d
10
7p
1
.  
Electron configuration of +1 ion: [Rn]7s
2
5f
14
6d
10
.  
Electron configuration of +3 ion: [Rn]5f
14
6d
10
. 
 
Beyond the Basics 
1.23  9, 5, 121. 
 
1.25  There are seven f orbitals. There are (at least) two separate ways of 
depicting them and designating them: the general set and the cubic set.  
The seven solutions for the cubic set are: x
3
, y
3
, z
3
, xyz, z(x
2
-y
2
), y(z
2
-x
2
), 
and x(z
2
-y
2
). The f x3 ,  f y3 ,  f z3  resemble the d z2  in that they have lobes along 
the particular axis, but with double ―doughnut‖ rings around the middle 
The Electronic Structure of the Atom      3  
 
rather than single rings. The other f orbitals resemble the d x2-y2 , d xy , d xz , 
and d yz  orbitals in that they consist of eight lobes (rather than four) 
between the axes. Several texts, such as that by Huheey, discuss f orbitals.  
See also E.A. Ogryzlo, On the Shapes of f Orbitals, J. Chem. Educ. 42 
(1965): 150–151 (1965) and refs. therein. 
 
1.27  Hydrogen heads the alkali metal group even though hydrogen is a non-
metal with unique properties.  Helium heads the alkaline earth metal group 
even though helium is better classified as a noble gas. 
 
4     Chapter 1  
 
 





1.1  Define  the  following  terms:  (a)  nodal  surface; 
(b) Pauli exclusion principle; (c) paramagnetic.
1.2  Define the following terms: (a) orbital; (b) degenerate; 
(c) Hund’s rule.
1.3  Construct a quantum number tree for the principal 
quantum number n 5 4 similar to that depicted for n 5 3 in 
Figure 1.3.
1.4  Determine the lowest value of n for which m l  can 
(theoretically) have a value of 14.
1.5  Identify the orbital that has n 5 5 and l 5 1.
1.6  Identify the orbital that has n 5 6 and l 5 0.
1.7  How  does  the  quantum  number  n  relate  to  the 
 properties of an orbital?
1.8  How  does  the  quantum  number  l  relate  to  the 
 properties of an orbital?
1.9  Explain concisely why carbon has two electrons in 
different p orbitals with parallel spins rather than the other 
possible arrangements.
1.10 Explain concisely why beryllium has a ground-state 
electron confi guration of 1s
2
2s
2
 rather than 1s
2
2s
1
2p
1
.
1.11 Write noble gas core ground-state electron confi g-
urations for atoms of (a) sodium; (b) nickel; (c) copper.
1.12 Write noble gas core ground-state electron confi g-
urations for atoms of (a) calcium; (b) chromium; (c) lead.
1.13  Write noble gas core ground-state electron confi gu-
rations for ions of (a) potassium; (b) scandium 31; (c) cop-
per 21.
1.14  Write noble gas core ground-state electron confi gu-
rations for ions of (a) chlorine; (b) cobalt 21; (c) manga-
nese 41.
1.15  Predict the common charges of the ions of thallium. 
Explain your reasoning in terms of electron confi gurations.
1.16  Predict the common charges of the ions of tin. Explain 
your reasoning in terms of electron confi gurations.
1.17  Predict the common charge of the silver ion. Explain 
your reasoning in terms of electron confi gurations.
1.18  Predict the highest possible charge of a zirconium ion. 
Explain your reasoning in terms of electron confi gurations.
1.19  Use  diagrams  similar  to  Figure  1.12  to  determine 
the number of unpaired electrons in atoms of (a) oxygen; 
(b) magnesium; (c) chromium.CHAPTER 1  •  The Electronic Structure of the Atom: A Review 18
BEYOND THE BASICS
1.23  The next set of orbitals after the f orbitals are the g
orbitals. How many g orbitals would there be? What would 
be the lowest principal quantum number n that would pos-
sess g orbitals? Deduce the atomic number of the fi rst ele-
ment  at  which  g  orbitals  would  begin  to  be  fi lled  on  the 
basis of the patterns of the d and f orbitals.
1.24  An alternative to the Schrödinger wave equation is 
the Dirac wave equation. Using online sources, research the 
Dirac wave equation and contrast it with the Schrödinger 
wave equation.
1.25  Use  an  advanced  inorganic  chemistry  text  as  a 
source of information on the f orbitals. What are their com-
mon features? How do they differ among themselves?
1.26  In  Section  1.3,  gadolinium  is  mentioned  as  having 
an electron confi guration that deviates from the lanthanoid 
pattern. Which element in the actinoids should show a simi-
lar deviation? What would be its electron confi guration?
1.27  In Figure 1.13, the elements are organized logically 
according to the order of orbital fi lling. Identify two disad-
vantages of organizing the elements in this way.
1.28  A philosophical question: Does an orbital exist even 
if it does not contain an electron? Discuss.
1.20  Use  diagrams  similar  to  Figure  1.12  to  determine 
the number of unpaired electrons in atoms of (a) nitrogen; 
(b) silicon; (c) iron.
1.21  Write  the  electron  confi guration  expected  for  ele-
ment 113 and the confi gurations for the two cations that it 
is most likely to form.
1.22 Which of the following species are hydrogen-like? 
(a) He
1
; (b) He
–
; (c) Li
1
; (d) Li
21
.