Bonding and Structure

Question 1

Define ionic bonding

Answer 1

The electrostatic attraction between a positive and negative ions. Holds together cations and anions in ionic compounds

Question 2

Draw dot and cross diagrams of Na2O and Magnesium bromide

Answer 2

Draw it an look at p11 of study pack

Question 3

Define covalent bonding

Answer 3

The strong electrostatic attraction between a shared pair of electrons and the nuclei of the bonded atoms

Question 4

Draw dot and cross diagrams of CO2 and PCl5

Answer 4

Look at p15 of stud pack

Question 5

What is the octet rule

Answer 5

That elements tend to combine in a covalent compound with 8 electrons in their outer shell

Question 6

What is a lone pair of electrons

Answer 6

A pair of electrons in the outer shell not used in bonding

Question 7

Define dative covalent bond

Answer 7

A special type of bond formed from 2 electrons form the same atom e.g. NH4+ (NH3 + H+ –> NH4+)
Both electrons have been donated by one atom

Question 8

Draw dot and cross diagram for NH4+ and H3O+

Answer 8

look at study pack p17

Question 9

Define average bond enthalpy

Answer 9

It is the average enthalpy change which takes place when breaking by homolytic fission one mole of a given type of bond in the molecules of a gaseous species.
Measurement of bond strength

Question 10

Define metallic bonding

Answer 10

The electrostatic attraction between positive metal ions and delocalised electrons.

Question 11

Why do metals have high melting and boiling points

Answer 11

A lot of energy is needed to overcome the strong electrostatic attraction between the cations and electrons.

Question 12

Why are metals good conductors of electricity

Answer 12

Solid- delocalised electrons are mobile so can carry charge

molten- delocalised electrons and the cations can move and carry charge

Question 13

Why are metals insoluble in water or non-polar solvents

Answer 13

Because the strong electrostatic attraction between the positive metal ions and electrons is too strong so a lot of energy is needed to overcome it.

Question 14

Which out of sodium, magnesium and aluminium is the best conductor of electricity

Answer 14

Aluminium- Has a charge of +3 so more delocalised electrons per metal ion, so has the best capacity to carry charge.

Question 15

Define malleable and ductile

Answer 15

Malleable- can easily be bent in to different shapes

Ductile- can be drawn in to a wire

Question 16

Which metals are present in stainless steel and brass

Answer 16

Stainless steel- Fe and Cr

Brass- Cu and Zn

Question 17

How does an alloy make a metal harder

Answer 17

Because each metal is slightly different sizes so they can’t easily slide over each other which means they are harder.

Question 18

Why do ionic compounds have high melting and boiling points

Answer 18

There is a strong electrostatic attraction between the +ve and -ve ions and a lot of energy is needed to overcome this.

Question 19

Do ionic compounds conduct electricity when solid and molten

Answer 19

solid- no- ions aren’t mobile as are in fixed lattice arrangement so can’t carry charge
Molten/ dissolved in water- Ions aren’t in fixed positions in the lattice structure so can move around and carry charge.

Question 20

Are ionic compounds soluble in water

Answer 20

Yes - often they have good solubility in water- water is polar so is attracted to the opposite charges in the compound- water molecules levers it out of it’s compound surrounding it by H2O molecules.

Question 21

Why are ionic compounds brittle

Answer 21

If there is even the smallest movement of a layer the positive ions will be next to other positive ions. this causes repulsion causing the structure to break apart.

Question 22

Giant covalent lattices- boiling points

Answer 22

High- There are strong covalent bonds which need to be broken which requires a lot of energy

Question 23

Simple covalent molecules- boiling points

Answer 23

Low- There have very weak intermolecular forces which are easy to overcome, so not much energy is required.

Question 24

Giant covalent lattice- Electrical conductor

Answer 24

No- there are no mobile electrons or any other charged particles which can carry charge.

Question 25

Simple covalent molecules- Electrical conductor

Answer 25

No- there are no mobile electrons or any other charged particles which can carry charge.

Question 26

Giant covalent lattice- Solubility in non-polar solvents

Answer 26

No- The strong covalent bonds that hold it together require too much energy to overcome

Question 27

Simple covalent molecules- Solubility in non-polar solvents

Answer 27

Yes- Weak intermolecular forces are easy to break, so the solvent molecules form similar intermolecular bonds with molecules.

Question 28

Draw structure of diamond

Answer 28

Draw it and check that each carbon atom is covalently bonded to 4 other carbon atoms. it is a tetrahedral shape

Question 29

Draw structure of graphite

Answer 29

Check it p30 of study pack- two layers and weak forces between the layers

Question 30

Diamond- Electrical conductor

Answer 30

No- Has no mobile electrons to carry charge

Question 31

Graphite- Electrical conductor

Answer 31

Yes- Carbon only forms 3 bonds so each has a spare electron which become delocalised so can move abd carry charge

Question 32

Diamond- hardness

Answer 32

Very hard- each carbon atom forms 4 bonds and forms a tetrahedral structure for each atom. Strong covalent bonds need much energy to break

Question 33

Graphite- hardness

Answer 33

Soft- there are weak intermolecular forces between layers which can be easily broken and the layers slide over each other.

Question 34

Define giant covalent lattices of atoms

Answer 34

It is a 3D structure of atoms which is bonded together by very strong covalent bonds.

Question 35

VSEPR (Valence Shell Electron Pair Repulsion) Theory states

Answer 35

1. Electron pairs around an atom will repel each other
2. They will tend to get as far apart as possible
3. Number and type of electron pairs determines the shape
4. Lone pairs repel more strongly than bonded pairs (this affects bond angle) reduction of about 2.5 degrees per lone pair.

Question 36

If a central atom has 2 bonding pairs and no lone pairs around it what shape and angle will it be?

Answer 36

Linear- 180 degrees

Question 37

If a central atom has 3 bonding pairs and no lone pairs around it what shape and angle will it be?

Answer 37

Trigonal planar- 120 degrees

Question 38

If a central atom has 4 bonding pairs and no lone pairs around it what shape and angle will it be?

Answer 38

Tetrahedral- 109.5 degrees

Question 39

If a central atom has 3 bonding pairs and 1 lone pairs around it what shape and angle will it be?

Answer 39

Trigonal pyramidal- 107 degrees

Question 40

If a central atom has 2 bonding pairs and 2 lone pairs around it what shape and angle will it be?

Answer 40

Non- linear - 104.5 degrees

Question 41

If a central atom has 6 bonding pairs and no lone pairs around it what shape and angle will it be?

Answer 41

Octahedral- 90 degrees

Question 42

Draw shape and state angle of:
PH3
GeCl2
BF4- ion
AsH3

Answer 42

PH3- trigonal pyramidal 107 degrees
GeCl2- non-linear- 117.5 degrees
BF4- ion- tetrahedral- 109.5 degrees
AsH3- Trigonal pyrimidal- 107 degrees

Question 43

What are the types of Van der Waals forces that exist

Answer 43

induced dipole-dipole and permanent dipole-dipole

Question 44

London forces description

Answer 44

Electrons are permanently moving
At any single instant their distribution in a molecule is not even.
This results in an instantaneous, temporary dipole.
This dipole induces dipoles in neighbouring molecules.
This leads to a small electrostatic attraction between the neighbouring charges in the dipoles.
This attraction between the molecules are London forces.

Question 45

2 factors that affect the strength of London forces

Answer 45

1. Number of electrons in a molecule- more electrons the stronger the force because there are greater fluctuations.
2. Contact between molecules- only an issue with molecules with approx. same number of electrons.
   Less branched molecules have a higher contact area so stronger London forces

Question 46

Define electronegativity

Answer 46

The ability of an atom to attract the bonding electrons in a covalent bond

Question 47

Define permanent dipole

Answer 47

A small charge difference between different atoms in a molecule. It does not change across a bond.
If there is a difference in electronegativity between atoms in a compound then they have partial charges and permanent dipoles.

Question 48

Define polar covalent bond

Answer 48

It’s a bond with a permanent dipole- contains partial negative and partial positive charges on the bonded atoms

Question 49

Define polar molecule

Answer 49

A molecule that has an overall dipole taking into account all dipoles across bonds and the shape of molecules.

Question 50

When are molecules with polar bonds not polar overall

Answer 50

When they are symmetrical

Question 51

Decide whether BeCl2, SnCl4 and CH2Cl2 are polar

Answer 51

BeCl2- Linear so won’t be polar
SnCl4- Tetrahedral- symmetrical so dipoles cancel each other out so not polar
CH2Cl2- Tetrahedral- C-H bond isn’t polar so dipoles don’t cancel each other out - is polar

Question 52

Define hydrogen bonding

Answer 52

A strong dipole-dipole attraction between an electron deficient hydrogen atom of -NH, -OH or -HF on one molecule and a lone pair of electrons on a highly electronegative atom containing N, O or F on a different molecule.

Question 53

Which of these molecules have hydrogen bonding:

H2S, CH3OH, PH3, NO2, CH3NH2, CH2=O

Answer 53

CH3OH and CH3NH2

the others can’t because they don’t have and N-H, F-H or O-H bonds

Question 54

Describe the density of ice compared to water

Answer 54

Ice is less dense than water. For a given volume there are fewer molecules of H2O in ice than in water. The molecules of H2O in solid ice are less closely packed than in liquid water.