Lecture 1: Group 15 Elements (PDF)

Summary

This lecture introduces Group 15 elements, also known as the pnictogens. It details the properties of nitrogen, phosphorus, arsenic, antimony, and bismuth, including their electronic configurations, melting points, boiling points, and common oxidation states. The lecture also covers trends in properties as you move down the group.

Full Transcript

Lecture 1
What are Group 15 Elements?
Group 15 elements are also called the Nitrogen family. It includes nitrogen,
phosphorus, arsenic, antimony and bismuth elements. The p-block elements
are also known as the Representative Elements which are placed on the
right side of the main periodic table.

So, in Group 15 elements as you would move down a group, starting with
the lightest element and finishing with the heavy ones; you’d notice a general
flow in properties as you move down the order. For eg, Nitrogen is a gas and
non-metal but as you move down the group, we encounter metalloids and
then at the bottom, metal i.e. Bismuth. These trends in the periodic table help
 us better understand the behavior of atoms and also helps us predict new
elements.

Property Nitrogen Phosphorus Arsenic Antimony Bismuth

Atomic symbol N P As Sb Bi

Atomic number 7 15 33 51 83

Atomic mass (amu) 14.01 30.97 74.92 121.76 209.98

Valence electron
[He]2s2 2p3 [Ne]3s2 3p3 [Ar]3d10 4s24p3 [Kr]4d10 5s25p3 [Xe]4f14 5d106s26p3
configuration

Melting point – 210 44.15 817 631 271

Boiling point (°C) -196 281 603(sublimes) 1587 1564

Density (g/cm3) at
1.15(g/L) 1.8 5.7 6.68 9.79
25°C

Atomic radius (pm) 56 98 114 133 143

First Ionization
1402 1012 947 834 703
energy (kJ/mol)

Common Oxidation
-3 to +5 +5, +3, -3 +5, +3 +5, +3 +3
state(s)

Ionic radius (pm) 146(-3) 212(-3) 58(+3) 76(+3) 103(+3)

Electronegativity 3.0 2.2 2.2 2.1 1.9

1. Electronic Configuration

 The valence shell electronic configuration plays a major role in how an
element behaves. The valence electron shell configuration of group
15 elements is ns2np3.
 All the group 15 elements have the same arrangement and this is why
they’re similar.
 The s-orbital in this group is completely filled and the p-orbitals are
half filled and this makes their configuration extra stable.
2. Atomic and Ionic Radii

 If you see the electronic configuration of elements in the table above,
you will notice that with every step you move downwards, new orbitals
are added to the atom.
 This addition of new orbitals increases both the Atomic and the Ionic
radii of group 15 elements.
 However, we see that from Arsenic to Bismuth only a small increase in
ionic radius is observed.
 This is due to the presence of completely filled d and/or f orbitals in
heavier members.

3. Ionization Enthalpy

 Ionization Energy is the amount of energy required to remove an
electron from the outermost orbit of the atom.
 This is basically a measure of how hard the nucleus is holding on to
the electron.
 The closer the electron is to the nucleus the stronger its hold and thus
the energy required is more.
 As we move down the group, the radius of the atom increases, and
therefore the Ionization energy decreases due to the weaker hold of
the nucleus.

4. Electronegativity

 The electronegativity value decreases down the group with increasing
atomic size.
 This again is due to the increasing distance between the nucleus and
the valence shell as we move down the group.

5. Physical Properties

 All the elements of the group exist in a polyatomic state.
 First, Nitrogen is gas, but as you move down, there is a significant
increase in the metallic character of the elements.
 Nitrogen and Phosphorus are non-metals, Arsenic and Antimony are
metalloids and Bismuth is a metal.
  These changes can be attributed to the decrease in Ionization enthalpy
and increase in atomic size.
Boiling points also, in general, show an increasing trend as you move down.(
What happens to the boiling point as you move down the group?
The atoms increase in size, as they gain extra electron shells, and the
intermolecular forces become stronger. More energy is required to break
these forces, thus there are higher melting and boiling points as you go down
the group).

6. Chemical Properties

 The valence shells of the p-Block elements have a configuration of
ns2 np3.
 So, the elements here can either lose 5 electrons or gain 3.
 The common oxidation states of these elements are -3, +3 and +5.
 With a decrease in the Ionization enthalpy and electronegativity due
to the increasing atomic radius, the tendency to gain three electrons
to create a -3 oxidation state decreases down the group.
 In fact, Bismuth hardly forms any compounds with a -3, oxidation
state.
 As we go down, the stability of the +5 state decreases and that of +3
increases due to the inert pair effect.

 Q1/ Why is Group 15 called P block?
 It is a p-block element since it takes the physical and chemical
properties after that of other p-block elements of the eighteenth
group. P-block elements are generally non-metals, while the
remaining are metalloids and metals.
Two of the most dissimilar nonmetallic elements are in the same group:
reactive phosphorus and unreactive nitrogen. Of the other members of the
group, arsenic is really a semimetal, and the two lower members of the
group, antimony and bismuth, exhibit weakly metallic behavior.
Nitrogen and phosphorus are both nonconductors of electricity,
and both form acidic oxides, so they are unambiguously classified
as nonmetals.
Although they are vertical neighbors in the periodic table, the redox behavior
of nitrogen and phosphorus could not be more different. Whereas the higher
oxidation states of nitrogen are strongly oxidizing in acidic solution, those of
phosphorus are quite stable. In fact, the highest oxidation state of
phosphorus is the most thermodynamically stable and the lowest oxidation
state, the least stable—the converse of nitrogen chemistry.( While both
nitrogen and phosphorus can exist in a +3 and +5 oxidation state, there are
factors that make the +5-oxidation state more stable for phosphorus than it
is for nitrogen. Nitrogen has a strong N=N triple bond, which asks for a lot
of energy to form compounds, making it less stable in its +5 oxidation state.
In contrast, phosphorus can use its d orbitals to form more bonds and thus
stabilize its +5 oxidation state. A classic example is that nitrogen forms only
NF3, whereas phosphorus can form both PF3 and PF5. The ability to use d
orbitals to form more bonds provides extra stability to the +5 oxidation state
in phosphorus).
Frost diagram comparing the stability of the oxidation states of phosphorus and nitrogen
in acidic solution

The Thermodynamic Stability of Dinitrogen:
1-If we look at the bond energies, we can see why different species are
preferred for the two elements. Dinitrogen, N2, is the stable form for the
element, and it is a common product from nitrogen-containing compounds in
chemical reactions. This is, in large part, due to the very high strength of the
nitrogen- nitrogen triple bond compared to the single (or double) bonds.
2-Thus, elemental phosphorus contains groups of singly bonded phosphorus
atoms. In fact, the strong phosphorus-oxygen single bond becomes a
dominant feature of phosphorus chemistry. For example, as we will see
below, whereas the element nitrogen is very stable to oxidation, elemental
phosphorus reacts vigorously with oxygen to give oxides.
3-The triple nitrogen-nitrogen bond energy is greater even than that for the
triple carbon-carbon bond (Table 15.4). Conversely, the single bond between
two nitrogen atoms is much weaker than the carbon-carbon single bond. It
is this large difference between N‚N and N¬N bond strengths (742 kJ/mol–
1) that contributes to the preference in nitrogen chemistry for the formation
of the dinitrogen molecule in a reaction rather than chains of nitrogen-
nitrogen single bonds, as occurs in carbon chemistry. Furthermore, the fact
that dinitrogen is a gas means that an entropy factor also favors the formation
of the dinitrogen molecule in chemical reactions.

4-We can see the difference in behavior between nitrogen and carbon by
comparing the combustion of hydrazine, N2H4, to that of ethene, C2H4.
The nitrogen compound burns to produce dinitrogen, whereas the carbon
compound gives carbon dioxide:
The Bonding Limitations of Nitrogen:
1-Nitrogen forms only a trifluoride, NF3, whereas phosphorus forms two
common fluorides, the pentafluoride, PF5, and the trifluoride, PF3. It is
argued that the nitrogen atom is simply too small to accommodate more than
the three fluorine atoms around it, while the (larger) lower members of the
group can manage five (or even six) nearest neighbors

Why there arise negative oxidation state for N? Because of the difference in
the EN between H=2.1 & N=3.0.
Example :-NH3 (N -III), N2H4 (-II), NH2OH(-I) ,N2 (0), N2O (+I), NO (+II),
HNO2(+III), NO2(+IV) & HNO3(+V).
Nitrogen can fill the outer shell to be 8es by:
1. Gains 3es forming N3- (Nitrides of alkaloids elements)
2. Forming single covalent. Bonds (e.g.NH3) or multiple (e.g. N≡N).
3. Forming covalent bonds with loosing e.g. [NH4] +
4. forming covalent bonds with gaining e.g. NH2- amide.

There will be stable nitrogen compounds, the outer shell of nitrogen is
incomplete (e.g.NO or NO2) each N contains one unpaired e. They have
paramagnetic properties. Nitrogen forms multiple bonds differing from the
other gr. elements, so it likes C & O. The bond (N-N) is weaker than that in
(C-C) because of the repulsion of the non bonding electrons on the Nitrogen
atoms.