Chapter 7

Question 1

Across period 2 what sub shells are occupied?

Answer 1

2s and 2p

Question 2

Across period 3 what sub shells are occupied?

Answer 2

3s, 3p

Question 3

Across period 4 what sub shells are occupied?

Answer 3

Although 3d is involved in the highest subshell, only 4s and 4p are occupied.

Question 4

What is the trend down the group?

Answer 4

Elements in a group have the same number of electrons in each shell. This similarity in configuration gives elements in the same group similar properties.

Question 5

Why are blocks used?

Answer 5

The elements are broken into blocks corresponding to the highest sub shell.

Question 6

How is the atomic number of elements within a periodic table arranged?

Answer 6

From left to right elements are arranged in increasing atomic number (proton number).

Question 7

How is the groups of elements within a periodic table arranged?

Answer 7

Elements are arranged in vertical columns called groups. Each element in that group has the same number of outer shell electrons with similar properties.

Question 8

How is the periods of elements within a periodic table arranged?

Answer 8

They are arranged in horizontal rows, the period number gives the highest energy electron shell in an elements atoms.

Question 9

What is periodicity?

Answer 9

The repeating trend in properties of elements across a period.

Question 10

What does ionisation energy measure?

Answer 10

How easily an atom loses electrons to form positive ions.

Question 11

What is meant by the first ionisation energy?

Answer 11

The energy required to remove one electron from each atom in one mole of gaseous atoms of an element forming one mole of gaseous 1+ ions. Units is KJ per mole.

Question 12

Where is the first electron lost?

Answer 12

It is lost from the highest energy level as it has the least amount of attraction from the nucleus.

Question 13

What are the factors affecting ionisation energy?

Answer 13

Atomic radius, nuclear charge and electron shielding.

Question 14

How does the atomic radius affect the ionisation energy?

Answer 14

The greater the distance between the outer shell and the nucleus the less nuclear attraction. The force of attraction falls off sharply with increasing distance from the nucleus to the electrons.

Question 15

How does nuclear charge affect the ionisation energy?

Answer 15

The greater the amount of protons in the nucleus the greater the attraction between the nucleus and the outer shell attractions

Question 16

How does electron shielding affect the ionisation energy?

Answer 16

Electrons are negatively charged so the inner electrons repel the outer shell electrons this repulsion is called the shielding effect which reduces the attraction.

Question 17

Describe the trend in the first ionisation energy?

Answer 17

A general increase in first ionisation energy across each period. A sharp decrease in first ionisation energy between the end of one period and the start of the next.

Question 18

How many ionisation energies can an element have?

Answer 18

It can have as many ionisation energies as there are electrons.

Question 19

What is the second ionisation energy?

Answer 19

The energy required to remove one electron from each iron in one mole of gaseous 1+ ions of an element to form one mole of gaseous 2+ ions.

Question 20

Describe the second ionisation energy of helium?

Answer 20

It is greater as the two protons attracted to electrons in the 1s shell. After losing the first electron there is a greater nuclear attraction so more ionisation energy is needed to remove the second electron.

Question 21

What does a large increase between certain ionisation energies suggest?

Answer 21

That an electron has to be removed from a different shell which is closer to the nucleus with less shielding.

Question 22

Describe the trends in first ionisation energies down a group?

Answer 22

The atomic radius increases, more inner shells so shielding increases, nuclear attraction decreases, first ionisation energy decreases.

Question 23

Describe the trends in first ionisation energies across a period?

Answer 23

Nuclear charge increases, same shell so have similar shielding, nuclear attraction increases with atomic radius decreases. The first ionisation energy increases.

Question 24

How do you work out the second ionisation energy?

Answer 24

You add the first ionisation energy and the second together.

Question 25

Why is there a drop in ionisation energies?

Answer 25

It is due to subshells, their energies and how orbital is filled with electrons.

Question 26

State the trend within the first ionisation energy?

Answer 26

A rise from lithium to beryllium. A fall to boron followed by a rise to carbon and nitrogen. A fall to oxygen followed by a rise to fluorine and neon.

Question 27

Compare beryllium to boron in terms of ionisation energies?

Answer 27

The fall in ionisation energy marks the filling of the 2p subshell. The 2p sub shell in boron has a higher energy than the 2s sub shell in beryllium. Therefore the 2p electron in boron is easier to remove than one in the 2s shell in beryllium. The first ionisation is lower in boron than in beryllium

Question 28

Compare nitrogen and oxygen in terms of ionisation energies?

Answer 28

In nitrogen and oxygen the highest energy levels for electron is in the 2p sub shell. In oxygen the paired electrons in one of the 2p orbital repel one another making it easier to remove an electron from an oxygen atom than a nitrogen atom. Therefore the first organisation energy of oxygen is less than the first ionisation of nitrogen.

Question 29

Is it easier to remove a spin paired electron or a half filled shell of electrons (one electron pair orbital)?

Answer 29

It is easier to remove a spin paired electron as it is less stable due to the fact that the electrons repel one another.

Question 30

What are semimetals/metalloids?

Answer 30

They are elements near the metal and non-metal divide and can show in between properties. The two metals in between the divide a silicon and germanium which are semimetals.

Question 31

At room temperature what state are metals at?

Answer 31

They are in solid state apart from mercury.

Question 32

What is metallic bonding?

Answer 32

It is the strong electrostatic attraction between metal cations and delocalised electrons.

Question 33

Describe the structure in metallic bonding?

Answer 33

Cations are fixed in position maintaining the shape and structure of the metal. The delocalised electrons are mobile and free to move across the whole structure meaning only the electrons can move. In a solid metal structure each atom has donated its negative outer shell electrons to a shared pool of delocalised electrons throughout the structure. The cations left behind consist of the nucleus and the inner electron shells of the metal ions.

Question 34

What is the structure described as of metals ?

Answer 34

A giant metallic lattice

Question 35

What are the properties of metals?

Answer 35

Strong metallic bonds – attraction between positive ions and delocalised electrons. High electrical conductivity and high melting and boiling point.

Question 36

Describe the periodic trend of melting points?

Answer 36

The melting point increases from group 1 to 14 (4). There is a sharp decrease in melting point from group 14 (4) and group 15 (5). The melting points are comparatively low from group 15 (5) to group 18 (0).

Question 37

What does the sharp decrease in melting point indicate?

Answer 37

A change from giant to simple molecular structures

Question 38

How are melting and boiling points different from giant structures to simple molecular structures?

Answer 38

Giant structures have strong forces so have high melting points to overcome them. For a simple molecular structures have low melting points as they have weak forces of attraction.

Question 39

Describe the electrical conductivity of metals?

Answer 39

Metals can conduct electricity in both solid and liquid state. When a voltage runs through the delocalised electrons carry the charge. This differs for ionic compounds as they can only conduct electricity in molten or aqueous states when the ions are free to move when solid they have no mobile charge carriers.

Question 40

Describe the melting and boiling points of metallic structures?

Answer 40

The melting point depends on the strength of the metallic bonds holding the atoms together in a giant metallic lattice. Most metals require large amounts of energy is to overcome the strong electrostatic attraction between the positive ions and the electrons resulting in a high melting and boiling point.

Question 41

Describe the solubility within metallic structures?

Answer 41

Metals are insoluble and don’t dissolve. Any interactions with lead to a reaction rather than dissolving.

Question 42

What are simple molecular lattice structures?

Answer 42

It’s when non metals are held together by weak intermolecular forces with strong covalent bonds between the atoms within the molecules.

Question 43

What three elements form giant covalent lattices?

Answer 43

Boron, carbon and silicon.

Question 44

What is a giant covalent lattice?

Answer 44

It’s when atoms are held together by network of strong covalent bonds to form a covalent lattice.

Question 45

Describe the structure of carbon and silicon?

Answer 45

They have four electrons in their outer shells. Carbon (in diamond form) and silicon use these for electrons to form covalent bonds with other atoms. Which result in a tetrahedral structure which bond angles of 109.5° by electron pair repulsion.

Question 46

What is graphite?

Answer 46

It’s when carbon uses three of its four outer shell electrons to form covalent bonds to other atoms with the remaining electron being released into a pool of delocalised electrons.

Question 47

What is the structure of graphite?

Answer 47

Graphic forms planar hexagonal layers with bond angles of 120° by electron repulsion theory. These layers are parallel which are held by weak London forces, despair electron is delocalised between the layer so electricity can be conducted. Between the layers that are strong covalent bonds.

Question 48

What are the physical properties of graphite?

Answer 48

High melting and boiling point
Insoluble
Conducts electricity (delocalised electrons free to move across the whole structure)

Question 49

What are the properties of giant covalent structures dominated by?

Answer 49

The strong covalent bonds making them difficult to break down.

Question 50

Explain the melting and boiling point of covalent structures?

Answer 50

They have a high melting and boiling point as the bonds found in the covalent lattice are very strong. High temperatures are required to provide large quantities of energy needed to break these bonds.

Question 51

Explain the solubility of giant covalent structures?

Answer 51

They are insoluble in most solvents, the covalent bonds are far too strong to be broken down by the interaction with solvents.

Question 52

Explain the electrical conductivity of giant covalent structures?

Answer 52

The giant covalent lattice doesn’t conduct electricity apart from graphene in graphite. In carbon silicon all for an outer electrons are involved in covalent bonding so unable for conducting electricity where is graphene and graphite can.

Question 53

What is graphene?

Answer 53

It is a single layer of graphite composed of hexagonally composed of carbon atoms attached by strong covalent bonds.

Question 54

Describe the structure of graphene?

Answer 54

It has a giant covalent structure of carbon based on hexagonal layers with bond angles of 120° by electron pair repulsion. The spare electron is released as a delocalise electron so is a good conductor of electricity.

Question 55

What are the two allotropes of carbon?

Answer 55

Graphite and graphene