2. The Periodic Table: Bonding and Structure

Question 1

How do outer electrons become delocalised?

Answer 1

The OUTER electrons of the metal ATOMS are loosely held which means they can become DELOCALISED.

Question 2

How does metallic bonding occur? What is the definition?

Answer 2

metal atoms LOSING their outer ELECTRONS to form a “common pool” of DELOCALISED electrons.

the ATTRACTION of these POSITIVELY charged ions for the delocalised ELECTRONS.

Question 3

What can metals be considered as?

Answer 3

a giant lattice of POSITIVE ions held together by these DELOCALISED electrons

Question 4

In order to melt or boil a metal you ..?

Answer 4

the METALLIC bonds need to be broken.

Question 5

High melting points mean?

Answer 5

STRONG metallic bonds.

Question 6

What is the trend for the boiling point (metallic bonding) of group one?

Answer 6

METALLIC BONDING DECREASES

Question 7

What is the full explanation of boiling point (metallic bonding) in group one?

Answer 7

As you go down the group the boiling point DECREASES. So the metallic bonding must get WEAKER.

As you go down the group the outer ELECTRONS are FURTHER away from the nucleus (the number of energy levels has INCREASED).

The strength of the metallic bond gets WEAKER as the outer electrons are further away from the POSITIVE charge of the NUCLEUS.

Question 8

What is the trend for boiling point (metallic bonding) in metals across a period?

Answer 8

metallic bonding INCREASES.

Question 9

What is the full explanation of metallic bonding across a period

Answer 9

As you go across a period the metallic bonding gets STRONGER(as the boiling point is INCREASING ).

As you go across the period the number of OUTER electrons is INCREASING meaning there are more DELOCALISED electrons

so the metallic bond is STRONGER.

Question 10

Noble gases are said to be?

Answer 10

MONATMOIC. existing as SINGLE ATOMS

Question 11

What does monatomic mean?

Answer 11

They only exist as single atoms (noble gases)

Question 12

Forces between monatomic noble gases are?

Answer 12

They are very low. This means the forces between are very weak

Question 13

How do London Dispersion Forces arise?

Answer 13

The ELECTRONS in an atom may become unevenly distributed causing a TEMPORARY dipole

one side of the atom becomes slightly NEGATIVE ( δ- ) while the other side becomes slightly POSITIVE ( δ+ ).

These dipoles only exist for a fraction of a second but this has a knock on effect on the neighbouring atoms.

The δ- on one atom attracts the δ+ on a neighbouring atom. It’s this weak attraction BETWEEN the atoms that is the LONDON DISPERSION FORCE

The temporary dipole in one atom INDUCES a temporary dipole in a neighbouring atom so you get the attraction between the δ+ and δ- in the neighbouring atoms.

Question 14

Where do LDF’s exist?

Answer 14

BETWEEN particles

Question 15

Compared to other intermolecular forces, where to LDF’s lie

Answer 15

They are the weakest compared to the 2 others

Question 16

As the size of atoms increase, what happens? Why?

Answer 16

The strength of LDF’s increases as the size of the atoms increase.

This is because as the atomic number increases there are more ELECTRONS.

Question 17

What is a covalent bond?

Answer 17

A covalent bond is the electrostatic attraction between two positive nuclei and a shared pair of electrons.

Question 18

The simplest molecular elements are?

Answer 18

diatomic (2 atoms joined together)

Question 18

The simplest molecular elements are?

Answer 18

diatomic (2 atoms joined together)

Question 19

What are the diatomic elements?

Answer 19

H2, N2, O2, F2, Cl2, Br2 and I2

Question 20

Where are LDF’s located?

Answer 20

These weak forces exist between all atoms and molecules

Question 21

What can LDF’s tell about a substance?

Answer 21

strong enough to determine the physical properties (e.g melting/boiling point) of the molecular elements.

Question 22

What happens to the halogens when you go down a group?

Answer 22

The melting point increases.

Question 23

Give a full explanation of what happens when you go down group 7 (halogens)

Answer 23

The melting point INCREASES as you go down the GROUP.

This is because as the ATOMIC number increases the number of ELECTRONS present in the atoms also INCREASES.

As there are more ELECTRONS present within the diatomic molecules there are stronger INTER MOLECULAR forces and so more energy is needed to break them.

Question 24

When covalent molecular substances are melted/boiled what happens?

Answer 24

no COVALENT bonds are actually broken.

It is only the weaker intermolecular forces (LONDON DISPERSION FORCES) that are actually broken.

Question 25

What are the two ‘special’ molecules?

Answer 25

Sulfur and Phosphorous

Question 26

What so phosphorus and sulfur exist as?

Answer 26

DISCRETE molecules

Question 27

What are the formulas for sulfur and phosphorous

Answer 27

P4 and S8

Question 28

As a molecule gets bigger?

Answer 28

the melting point INCREASES

Question 29

What is the full explanation of melting point increasing?

Answer 29

As the molecule get bigger the melting point INCREASES.

This is because there are more (and larger) atoms present in the molecule so there are more electrons present.

As there are more electrons there are more LDFs (London Dispersion Forces) present which means it takes more energy to separate the molecules hence the increase in melting point.

Question 30

When you melt a substance, are covalent bonds broken? Why not?

Answer 30

It’s only the weak intermolecular LDFs that are broken no covalent bonds get broken when you melt or boil a molecular substance.

Question 31

What are the 3 forms of carbon?

Answer 31

diamond, graphite and fullerene

Question 32

What is a fullerene?

Answer 32

Fullerenes exist as covalent molecules with a definite formula.

Question 33

What is a fullerene that you know of? What is its formula?

Answer 33

C60 - buckministerfullerene

Question 34

What do the structures of fullerenes look like?

Answer 34

They are a large family of ‘carbon cage’ molecules each made up of rings of 5 and 6 carbon atoms.

They can also exist as nanotubes

Question 35

In groups 5, 6 and 7 what are the forces present in the molecule?

Answer 35

Intramolecular are all strong COVALENT bonds

Intermolecular are weak LDF’s

Question 36

What are the two types of covalent elements?

Answer 36

Covalent Molecular

Covalent Network

Question 37

What are Covalent Networks? How hard is it to break them?

Answer 37

Covalent Networks are huge structures with every atom being linked to other atoms by COVALENT BONDS.

As COVALENT bonds are very STRONG it takes a large amount of energy to BREAK the bonds.

This results in covalent network substances having very HIGH melting and boiling points.

Question 38

What are the two DISTINCT forms of graphite?

Answer 38

DIAMOND and GRAPHITE

Question 39

Explain in detail the structure of diamond

Answer 39

Each C atom forms 4 covalent bonds with neighbouring ATOMS.

All 4 outer electrons are used in bonding, there is no delocalised electrons, so diamond does NOT CONDUCT electricity

Strong covalent bonds are formed in 3D, they are tetrahedral

To cut or break diamond means that you have to break strong COVALENT bonds. It needs a lot of energy. The 3D network makes diamond very HARD.

Question 40

Explain in detail the structure of graphite

Answer 40

Each C atom forms 3 covalent bonds

Only 3 outer electrons are used in bonding, each C atom has 1 outer electron, so it CAN CONDUCT electricity

The covalent bonds are formed in 2D, so in SHEETS.

Between each sheet there is weak LDF’s present

The layers of C atoms can slip and slide, LUBRICANT

To cut or break graphite means breaking LDF’s which are very weak, so it is easy to break

Graphite is very brittle

Question 41

What are the elements that have a network structure?

Answer 41

BORON and SILICON

Question 42

What are the metallic elements?

Answer 42

Lithium, Beryllium, Sodium, Magnesium, Potassium, Calcium, Aluminium

Question 43

What are the covalent network elements?

Answer 43

Boron, Carbon and Silicon

Question 44

What are the covalent molecular elements?

Answer 44

Hydrogen, Nitrogen, Carbon, Phosphorus, Oxygen, Sulfur, Fluorine, Chlorine

Question 45

What are monatomic elements?

Answer 45

Helium, Neon, Argon

Question 46

What is covalent radius?

Answer 46

half the distance between the 2 nuclei in a covalent bond

Question 47

What is covalent radius measured in?

Answer 47

picometers

Question 48

As you go across a period, what happens to the atomic size? Why?

Answer 48

It DECREASES.

as the atomic number increases the number of protons in the nucleus is increasing so the electrons are pulled in tighter causing the atoms to get smaller.

Question 49

As you go down a group, what happens to the atomic size? Why?

Answer 49

As you go down a group the atomic size INCREASES.

This is because as you down the group you are adding extra shells of electrons so the atoms are bigger.

Sodium (2, 8, 1) is smaller than potassium (2, 8, 8, 1) as there is an extra shell of electrons in potassium.

Question 50

What is density?

Answer 50

mass per volume

Question 51

The greater the mass of an atom?

Answer 51

the greater the density

Question 52

The larger the atom?

Answer 52

The lower the density.

Question 53

When does atomic size only have an effect?

Answer 53

on solids and liquids i.e. when the atoms are CLOSE TOGETHER.

Question 54

Explain group 1’s density and atomic size

Answer 54

Group 1 has a LOW DENSITY, because they have a LARGE ATOMIC SIZE

Question 55

When you go across a period, what happens to the density in metals? Why?

Answer 55

the density INCREASES.

this is because the relative atomic mass is INCREASING and the covalent radius is DECREASING.

Question 56

What happens to the density when you go down a metal group? Why?

Answer 56

The density INCREASES

The RAM and SIZE of the metals INCREASES.

It increases, because the increase in RAM has an effect on the density too

Question 57

What happens to the first ionisation energy when you go across a period?

Answer 57

ionisation energy INCREASES

Question 58

Why does an increase in first ionisation energy happen when you go across a period?

Answer 58

This is because as the ATOMIC number increases extra PROTONS are added to the nucleus. So as the nuclear charge INCREASES this pulls the ELECTRON shells TIGHTER to the nucleus.

As the electrons are held MORE tightly to the nucleus it takes MORE energy to remove them. Therefore the first IONISATION energy INCREASES.

Question 59

What happens to the 1st ionisation energy when you go DOWN a group?

Answer 59

the first ionisation energy DECREASES

Question 60

Why when you go down a group, the first ionisation energy decreases?

Answer 60

1. The nuclear charge increases so more protons.
2. Extra energy level, outer electrons further away from nucleus
3. The extra layers of electrons shield the outer energy levels from the pull of the nucleus.
4. This means LESS energy is needed to pull off an electron from the outer energy level so the first ionisation energy DECREASES.

Question 61

What is the definition of first ionisation energy?

Answer 61

The First Ionisation Energy of an element is the energy required to remove 1 mole of electrons from 1 mole of atoms in the GAS state.

Question 62

What are the units of ionisation energy?

Answer 62

kilojoules per mole (kJmol-1)

Question 63

Where can you find the general equation for ionisation energies in the data book?

Answer 63

At the top of page 11

Question 64

What is the definition of 2nd ionisation energy?

Answer 64

The Second Ionisation Energy is the energy required to remove 1 mole of electrons from 1 mole of positive ions (+1 charge) in the gas state.

Question 65

What is the definition of the 3rd ionisation energy?

Answer 65

The THIRD ionisation energy is when a further mole of electrons is removed from ions with a 2+ charge.

Question 66

Explain why the second ionisation energy of an element is always greater than the first ionisation energy.

Answer 66

1. There are less electrons present after the first has been removed
2. The number of protons hasn’t changed so they are now pulling in a smaller number of electrons so they are pulled in tighter.
3. As the electrons are now held more tightly is takes more energy to pull another one off hence why the 2nd ionisation energy must be higher.

Question 67

Explain why the second ionisation energy of K is much greater than the second ionisation energy of Mg.

Answer 67

The electron arrangement for the elements are K(2,8,8,1) and Mg (2,8,2)

The electron arrangements for the ions are K+ (2,8,8) and Mg+ (2,8,1).

For the potassium the second electron would be removed from a full outer shell.

Remember a full outer shell is a stable electron arrangement so the K+ doesn’t want to lose this 2nd electron so the 2nd ionisation energy is high.

For the Mg+ the second electron is removed from a partially filed shell so it’s a lot easier to remove hence the lower 2nd ionisation energy value.

Question 68

How do you calculate the energy required for Mg(g) → Mg2+(g) + 2e- ?

Answer 68

First, you write the first and second ionisation energy equations

Mg(g) → Mg+(g) + e- 738 kJmol-1
Mg+(g) → Mg2+(g) + e- 1451kJmol-1

Then you add them together, the two Mg+ would cancel each other out.

Mg(g) → Mg2+(g) + 2e- 2189kJmol-1