Structure, Bonding & Properties of Matter

Question 1

How are ions made?

Answer 1

Made when electrons are transferred

Question 2

What are ions?

Answer 2

Charged particles

Question 3

When atoms lose or gain electrons to form ions, what are they trying to do?

Answer 3

To get a full outer shell (stable electronic structure)

Question 4

When metals form ions, what happens to their electrons and what type of ions do they form?

Answer 4

They lose electrons from their outer shell to form positive ions

Question 5

When non-metals form ions, what happens to their electrons and what type of ions do they form?

Answer 5

They gain electrons into their outer shell to form negative ions

Question 6

What does the charge on the ion represent?

Answer 6

Number of electrons lost or gained

Question 7

Explain ionic bonding

Answer 7

1. Non-metal gains electrons = negatively charged ion
2. Metal atom loses electrons = positively charged ion
3. Opposite charged ions are strongly attracted to one another by electrostatic forces

Question 8

What the structure of an ionic compounds called?

Answer 8

Giant ionic lattice

Question 9

How ions arranged in a giant ionic lattice? (forces?)

Answer 9

They’re closely packed with very strong electrostatic forces of attraction between oppositely charged ions - in all directions

Question 10

Name 3 properties of ionic compounds

Answer 10

1. High melting points
2. High boiling points
3. Dissolve easily in water

Question 11

When ionic compounds melt, what can they do and why?

Answer 11

Carry electric current bc ions are free to move

Question 12

Why do ionic compounds have high melting/boiling points?

Answer 12

Due to MANY strong bonds between ions = takes a lot energy to overcome this attraction (electrostatic forces)

Question 13

Draw the structure of sodium chloride

Answer 13

See mind map

Question 14

What is covalent bonding?

Answer 14

When non-metals bond together: share a pair of electrons to make covalent bonds

Question 15

Why are covalent bonds very strong?

Answer 15

Positively charged nuclei of bonded atoms are attracted to the shared pair of electrons by electrostatic forces

Question 16

Atoms only share electrons in their…

Answer 16

outer shells (highest energy levels)

Question 17

What does each covalent bond provide for each atom?

Answer 17

1 extra shared electron

Question 18

Atom involved generally makes enough covalent bonds…

Answer 18

to fill up its outer shell

Question 19

Draw the covalent bonds for water

Answer 19

See mind map

Question 20

Draw the covalent bonds for water in this form Cl-Cl

Answer 20

See mind map

Question 21

Draw the covalent bonds for ammonia

Answer 21

See mind map

Question 22

Draw the covalent bonds for ammonia in this form Cl-Cl

Answer 22

See mind map

Question 23

Draw the covalent bonds for hydrogen

Answer 23

See mind map

Question 24

Draw the covalent bonds for hydrogen in this form Cl-Cl

Answer 24

See mind map

Question 25

Draw the covalent bonds for hydrogen chloride

Answer 25

See mind map

Question 26

Draw the covalent bonds for hydrogen chloride in this form Cl-Cl

Answer 26

See mind map

Question 27

Draw the covalent bonds for methane

Answer 27

See mind map

Question 28

Draw the covalent bonds for methane in this form Cl-Cl

Answer 28

See mind map

Question 29

Draw the covalent bonds for oxygen

Answer 29

See mind map

Question 30

Draw the covalent bonds for oxygen in this form Cl-Cl

Answer 30

See mind map

Question 31

Usually substances containing covalent bonds, have what kind of structure?

Answer 31

Simple molecular structures

Question 32

For covalent compounds with a simple molecular structures, what the intramolecular forces like?

Answer 32

Very strong (covalent bonds)

Question 33

For covalent compounds with a simple molecular structures, what the intermolecular forces like?

Answer 33

Very weak (forces of attraction between molecules)

Question 34

Why do simple molecular substances have low melting/boiling points?

Answer 34

Feeble intermolecular forces need to be broken (NOT covalent bonds) = molecules are easily parted (little energy to overcome)

Question 35

What states are simple molecular substances at room temperature?

Answer 35

Most are gases or liquids

Question 36

Why is it that as a simple molecular substance gets larger, the melting/boiling points increases?

Answer 36

Strength of intermolecular forces increases = more energy needed to break them

Question 37

Why don’t simple molecular substances conduct electricity?

Answer 37

Because they aren’t charged = no free electrons or ions

Question 38

In giant covalent structures (macromolecules), how are all atoms bonded together?

Answer 38

By strong covalent bonds

Question 39

Why do macromolecules have very high melting/boiling points?

Answer 39

Lots of energy is needed to break covalent bonds between atoms

Question 40

Why don’t macromolecules conduct electricity?

Answer 40

Don’t contain charged particles = don’t conduct electricity (not even when molten)

Question 41

How many covalent bonds can carbon have?

Answer 41

4

Question 42

Why is diamond really hard?

Answer 42

Giant covalent structure - made up of carbon atoms that form four covalent bonds = makes it really hard

Question 43

Why does diamond have a really high melting point?

Answer 43

Strong covalent bonds take a lot of energy to break

Question 44

Why doesn’t diamond conduct electricity?

Answer 44

Because it has no free electrons/ions

Question 45

Describe the structure of graphite

Answer 45

Carbon atoms forms three covalent bonds = creating sheets of carbon atoms arranged in hexagons

Question 46

Why is graphite an ideal lubricating material?

Answer 46

1. Aren’t any covalent bonds between layers - only held together with weak forces
2. Layers can slide over each other = graphite slipperily

Question 47

Why doe graphite have a high melting point?

Answer 47

Covalent bonds in layers need a lot of energy to break

Question 48

Why can graphite conducts electricity and thermal energy?

Answer 48

Only three out of each carbon’s four outer electrons are used in bonds = carbon atoms has one electron that’s delocalised (free) and can move THROUGH whole structure

Question 49

What is graphene?

Answer 49

Sheet of carbon atoms joined together in hexagons (sheet is one atom thick)

Question 50

What do metals consist of?

Answer 50

Giant structures of atoms arranged in a regular pattern

Question 51

Explain metallic bonding

Answer 51

1. Electrons in outer shell are delocalised
2. Strong forces of electrostatic attraction between the positive metal ions and shared negative electrons
3. These forces of attraction hold the atoms together in a regular structure (known as metallic bonding)

Question 52

What produces the properties of metals?

Answer 52

Delocalised electrons in metallic bonds

Question 53

What does the condition of a metal depend on?

Answer 53

The ability of electrons to move through the metal

Question 54

Why are metals malleable?

Answer 54

Layers of atoms can slide over each other

Question 55

Why are metals solid at room temperature?

Answer 55

Electrostatic forces between metal atoms and delocalised electrons are very strong - lots of energy needed to broken
∴ Most have very high melting and boiling points

Question 56

Why are metals a good conductor of electricity and heat?

Answer 56

Delocalised electrons carry electrical current and thermal

energy through whole structure

Question 57

What are intermolecular forces?

Answer 57

Are forces that exist between molecules

Question 58

What are intramolecular forces?

Answer 58

Are the forces that hold atoms together within a molecule

Question 59

What are fullerenes?

Answer 59

Molecules of carbon, shaped like closed tubes or hollow balls

Question 60

What is the structure of fullerene like?

Answer 60

Made up of hexagon rings of carbon atoms

Question 61

What can fullerenes be used for? Name 4 things

Answer 61

1. Deliver a drug into body
2. Catalysts
3. Lubricants
4. Nanotubes

Question 62

How can fullerenes be used to deliver a drug into body?

Answer 62

They ‘cage’ other molecules = structure forms around another atom/molecule

Question 63

How can fullerenes be used as catalysts?

Answer 63

Individual molecules could be attached to fullerenes

Question 64

Why would fullerenes help make great industrial catalysts?

Answer 64

Because they have a large surface area

Question 65

Name 3 properties of nanotubes

Answer 65

1. Ratio between length and diameter of nanotubes = very high
2. Have high tensile strength (don’t break when stretched)
3. Conduct both electricity and thermal energy

Question 66

What can nanotubes be used for? Name 2 things

Answer 66

1. In electronics

2. Strengthen materials without adding much weight E.g. tennis racket frames

Question 67

How large a nanoparticles? (length and no. of atoms)

Answer 67

1-100nm, contain only a few hundred atoms

Question 68

Nanoparticles have a…

Answer 68

Large surface area to volume ratio

Question 69

As particles decrease in size…

Answer 69

size of surface area increases in relation to their volume

Question 70

What can having large surface area to volume ratio cause for nanoparticles?

Answer 70

For them to have different properties for the same material in bulk

Question 71

Why are some people worried about products containing nanoparticles?

Answer 71

Bc they’ve been made available before effects on human health have been investigated properly = we don’t know long term impacts on health will be