Topic 8 - Energetics I

Question 1

What is enthalphy change?

Answer 1

The heat change in a reaction at constant pressure.

Question 2

What is the symbol for enthalpy change?

Answer 2

ΔH

Question 3

What is the unit for enthalpy change?

Answer 3

kJ/mol

Question 4

What is the symbol ΔH° used for?

Answer 4

• Enthalpy change under standard conditions and with the elements in their standard state
• The ° indicates this (a circle with a line through it).

Question 5

What are standard states of elements?

Answer 5

Their physical states under standard conditions.

Question 6

What are standard conditions?

Answer 6

• 100kPa (about 1 atm)

* Specified pressure (normally 298K)

Question 7

What is an exothermic reaction?

Answer 7

One that gives out heat energy.

Question 8

What happens to the temperature of the system in an exothermic reaction?

Answer 8

It goes up.

Question 9

Give an example of an exothermic reaction.

Answer 9

Combustion of a fuel.

Question 10

What is an endothermic reaction?

Answer 10

One that takes in heat energy.

Question 11

What happens to the temperature of the system in an endothermic reaction?

Answer 11

It goes down.

Question 12

Give an example of an endothermic reaction.

Answer 12

Thermal decomposition of CaCO3.

Question 13

What is an enthalpy level diagram?

Answer 13

A diagram that shows the relative energies of the reactants and products in a reaction.

Question 14

Describe what an enthalpy level diagram looks like.

Answer 14

• Enthalpy on the y-axis, no x-axis
• Horizontal line for reactants and products -> No line joining the two
• Arrow between the two lines, showing ΔH

Question 15

What is another name for an enthalpy level diagram?

Answer 15

Energy level diagram

Question 16

How does enthalpy relate to how stable a substance is?

Answer 16

The lower a substance’s enthalpy, the more stable it is.

Question 17

Describe the enthalpy level diagram for an exothermic reaction.

Answer 17

• Reactants line above products line

* Downwards arrow between the two, showing ΔH

Question 18

Describe the enthalpy level diagram for an endothermic reaction.

Answer 18

• Reactants line below products line

* Upwards arrow between the two, showing ΔH

Question 19

What is a reaction profile diagram?

Answer 19

A diagram used to show how enthalpy changes throughout a reaction.

Question 20

Describe what a reaction profile diagram looks like.

Answer 20

• Enthalpy on y-axis, Progress of reaction on x-axis
• Horizontal line for reactants and products
• Curve between the two -> Peak up to activation, then falls to products
• Arrow up to peak = Activation energy (Ea)
• Arrow from reactants to products = ΔH

Question 21

What is the activation energy of a reaction?

Answer 21

The energy that must be supplied to break bonds in the reactants and start a chemical reaction.

Question 22

What is the symbol for activation energy?

Answer 22

Ea

Question 23

What is the ΔH value for an exothermic reaction?

Answer 23

Negative

Question 24

What is the ΔH value for an endothermic reaction?

Answer 24

Positive

Question 25

Describe the reaction profile diagram for an endothermic reaction.

Answer 25

• Products line is above reactants line
• Curve from reactants to peak above products, then falls to products
• Arrow upwards from reactants to products, showing ΔH
• Arrow upwards from reactants to peak, showing Ea

Question 26

Describe the reaction profile diagram for an exothermic reaction.

Answer 26

• Products line is below reactants line
• Curve from reactants to peak above products, then falls further to products
• Arrow downwards from reactants to products, showing ΔH
• Arrow upwards from reactants to peak, showing Ea

Question 27

How is the stability of a substance shown on an enthalpy level diagram or reaction profile diagram and why is this?

Answer 27

• The height of the reactants or products line shows the how unstable a substance is.
• Because a higher enthalpy corresponds with a low stability.

Question 28

In an exothermic reaction, are the reactants or products more stable?

Answer 28

Products (since they have a lower enthalpy)

Question 29

In an endothermic reaction, are the reactants or products more stable?

Answer 29

Reactants (since they have a lower enthalpy)

Question 30

Looking at an enthalpy level diagram and reaction profile diagram, how can you find the:
• Activation energy
• Enthalpy change

Answer 30

ENTHALPY LEVEL DIAGRAM:
• Activation energy -> Can’t be found!
• Enthalpy change -> From reactants to products line
REACTION PROFILE DIAGRAM:
• Activation energy -> From reactants line to peak of curve
• Enthalpy change -> From reactants to products line

Question 31

Can you measure the actual enthalpy of a system?

Answer 31

No, only the enthalpy change of a reaction.

Question 32

Why must enthalpy change be measured under standard conditions?

Answer 32

Changes in enthalpy are affected by temperature and pressure.

Question 33

What is 298K in *C?

Answer 33

25*C

Question 34

What are the different types of enthalpy change?

Answer 34

• Standard enthalpy change of reaction
• Standard enthalpy change of formation
• Standard enthalpy change of combustion
• Standard enthalpy change of neutralisation

Question 35

What is the standard enthalphy of reaction?

Answer 35

The enthalpy change when the reaction occurs in the molar quantities shown in the chemical equation, under standard conditions.

Question 36

What is the standard enthalpy of formation?

Answer 36

The enthalpy change when 1 mole of a ompound is formed from its constituent elements in their standard states, under standard conditions.

Question 37

Give an equation for the standard enthalpy of formation of ethanol.

Answer 37

2C (s) + 3H2 (g) + 1/2O2 (g) -> C2H5OH (l)

Question 38

What is the standard enthalpy of combustion?

Answer 38

The enthalpy change when 1 mole of a substance is completely burned in oxygen, under standard conditions.

Question 39

What is the standard enthalpy of neutralisation?

Answer 39

The enthalpy when an acid and an alkali react together to form 1 mole of water, under standard conditions.

Question 40

When defining what different type of ΔH are, what is it important to remember?

Answer 40

Include “under standard conditions” at the end of each definition.

Question 41

What is the symbol for the standard enthalpy of reaction?

Answer 41

ΔrH°

Question 42

What is the symbol for the standard enthalpy of formation?

Answer 42

ΔfH°

Question 43

What is the symbol for the standard enthalpy of combustion?

Answer 43

ΔcH°

Question 44

What is the symbol for the standard enthalpy of neutralisation?

Answer 44

ΔneutH°

Question 45

To work out the enthalpy change in an experiment, what things do you need to know?

Answer 45

• Number of moles of the substance reacting

* Change in temperature

Question 46

Is the heat change of a system equal to the enthalpy change?

Answer 46

Only if the pressure is kept constant.

Question 47

What is calorimetry?

Answer 47

Measuring temperature changes.

Question 48

How can you measure the temperature change in a reaction between two liquids or solids?

Answer 48

1) Set up a polystyrene beaker with a thermometer and a lid.
2) Mix the reactants inside and measure the temperature change every 30 seconds.
3) Use the graph method to minimise error (see flashcard).

(See pg 106 of revision guide)

Question 49

What is the problem with measuring the temperature change of a reaction between two solids or liquids?

Answer 49

Lots of heat is lost to the surroundings (or gained, if the reaction is endothermic).

Question 50

What method can be used to minimise the error in measuring the temperature change of a reaction between two solids or liquids?

Answer 50

1) Measure the temperature throughout the reaction every 30 seconds
2) Plot a graph of temperature against time -> There will be a curve
3) Extrapolate the curve from the RHS of the peak or trough to the left until the start of the reaction
4) Read off the temperature at the time when the reaction started
5) Compare this with the initial temperature reading to find the temperature change

(See pg 106 of revision guide)

Question 51

Remember to practise drawing temperature-time graphs for a reaction and extrapolating to find the temperature change.

Answer 51

Pg 106 of revision guide

Question 52

How can you measure the temperature change in a combustion reaction?

Answer 52

1) Set up a calorimeterr with the fuel underneath it.

2) Measure the temperature change of the reaction.

Question 53

Describe the structure of a calorimeter.

Answer 53

• Spirit burner inside combustion chamber with air supply
• Combustion chamber surrounded by water tank
• Water tank has a stirrer and thermometer inside

(See diagram pg 106 of revision guide)

Question 54

What is the problem with using a calorimeter to measure the temperature change of combustion?

Answer 54

Some heat is lost to the surroundings and apparatus.

Question 55

What is the equation for the energy change in a calorimetry experiment?

Answer 55

Q = m x c x ΔT

Where:
• Q = Energy change (J)
• m = Mass of substance being heated (g)
• c = Specific heat capacity of substance being heated (J/g/K)
• ΔT - Change in temperature of substance being heated (K)

Question 56

What is specific heat capacity?

Answer 56

The amount of energy needed to raise the temperature of 1g of a substance by 1K.

Question 57

What is the specific heat capacity for water?

Answer 57

4.18 J/g/K

Question 58

In the equation “Q = mcΔT”, what is m the mass of?

Answer 58

The substance being heated, NOT the fuel.

Question 59

How can you work out the enthalpy change per mole of a calorimetry reaction?

Answer 59

• Measure the temperature change using the right method
• Calculate the energy change (Q) using “Q = mcΔT”
• Work out the number of moles of the limiting reactant / fuel
• ΔH = Q / Moles

Question 60

In a lab experiment, 1.16g of an organic liquid fuel was completely burned in oxygen. The heat formed during this combustion raised the temperature of 100g of water from 17.5C to 80.0C. Calculate the standard enthalpy of combustion of the fuel. Its Mr is 58.0.

Answer 60

1) Q = m x c x ΔT
Q = 100 x 4.18 x (80.0 - 17.5) = 26125J = 26.125kJ
2) Moles = 1.16 / 58.0 = 0.0200 mol
3) ΔcH° = 26.125 / 0.0200 = -1310kJ/mol

Question 61

Give some reasons why the final ΔcH° value in an experiment might be smaller than the quoted value.

Answer 61

1) Some heat may have escaped through the calorimeter
2) Incomplete combustion of fuel
3) Conditions not standard

Question 62

Remember to ask teacher about the definition of ΔH - is it defo per mole.

Answer 62

Do it!

Question 63

State Hess’s Law.

Answer 63

The total enthalpy change of a reaction is always the saem, no matter which route is taken.

Question 64

What is Hess’s Law useful for?

Answer 64

Working out enthalpy changes that you can’t find directly by doing an experiment.

Question 65

What are the diagrams for Hess’s Law called?

Answer 65

Enthalpy cycles.

Question 66

How does an enthalpy cycle diagram work?

Answer 66

• Write the reaction you’re trying to calculate along the top
• Look at the values you are given
• Write the intermediate step along the bottom and draw the arrows for the values you are given
• Add any reverse arrows as dotted lines
• Work out the overall enthalpy change, remembering to multiply by the number of moles where necessary

Question 67

In enthalpy cycles, when writing elements along the bottom line, what must you remember?

Answer 67

They must be in their standard state and as molecules (not atoms).

Question 68

In enthalpy cycles, what are the two enthalpies you might need to use?

Answer 68

• Enthalpies of formation

* Enthalpies of combustion

Question 69

SO2 (g) + 2H2S (g) -> 3S (s) + 2H2O (l)

Work out the standard enthalpy of reaction, given that:
ΔfH°[SO2 (g)] = -297 kJ/mol
ΔfH°[H2S (g)] = -20.2 kJ/mol
ΔfH°[H2O (l)] = -286 kJ/mol

Answer 69

-235 kJ/mol

See pg 108 of revision guide

Question 70

2NH4NO3 (s) + C (s) -> 2N2 (g) + CO2 (g) + 4H2O (l)

Work out the standard enthalpy of reaction, given that:
ΔfH°[NH4NO3 (s)] = -365 kJ/mol
ΔfH°[CO2 (g)] = -394 kJ/mol
ΔfH°[H2O (l)] = -286 kJ/mol

Answer 70

-808 kJ/mol

See pg 108 of revision guide

Question 71

2C (s) + 3H2 (g) + 1/2O2 (g) -> C2H5OH (l)

Work out the standard enthalpy of reaction, given that:
ΔcH°[C (s)] = -394 kJ/mol
ΔcH°[H2 (g)] = -286 kJ/mol
ΔcH°[C2H5OH (l)] = -1367 kJ/mol

Answer 71

-279 kJ/mol

See pg 108 of revision guide

Question 72

Are the enthalpies of formation and combustion the only things that you might include in an enthalpy cycle?

Answer 72

No, you could also you different reactions with a common product, like neutralisation reactions.

Question 73

Experimentally, how can you find the enthalpy of reaction for:
CaCO3 (s) -> CaO (s) + CO2 (g)

Answer 73

• You can’t simply measure the temperature change, because the reaction is endothermic but requires heating
• Instead, carry out a neutralisation reaction with HCl of both CaCO3 and CaO
• Then draw an enthalpy cycle to work out the enthalpy of reaction

Question 74

CaCO3 (s) -> CaO (s) + CO2 (g)

Work out the standard enthalpy of reaction, given that:
ΔH1 = CaCO3 + 2HCl -> CaCl2 + CO2 + H2O
ΔH2 = CaO + 2HCl -> CaCl2 + H2O

Answer 74

Top line of cycle: CaCO3 (s) + 2HCl -> CaO (s) + CO2 (g) + 2HCl
Bottom line of cycle: CaCl2 + H2O + CO2

Therefore, the enthalpy change = ΔH1 - ΔH2

(See pg 109 of revision guide)

Question 75

What is the standard enthalpy of formation for elements?

Answer 75

0

Question 76

Remember to revise Hess’s law and enthalpy cycle diagrams.

Answer 76

Pg 108-109 of revision guide.

Question 77

Is breaking bonds endothermic or exothermic?

Answer 77

Endothermic

Question 78

Is forming bonds endothermic or exothermic?

Answer 78

Exothermic

Question 79

Does breaking bonds give a positive or negative ΔH value?

Answer 79

Positive

Question 80

Does forming bonds give a positive or negative ΔH value?

Answer 80

Negative

Question 81

If the energy in breaking bonds is greater than in forming them, is ΔH positive or negative?

Answer 81

Positive

Question 82

If the energy in breaking bonds is smaller than in forming them, is ΔH positive or negative?

Answer 82

Negative

Question 83

Why is energy needed to break bonds?

Answer 83

You need energy to overcome the attraction between the bonded atoms.

Question 84

What is bond enthalpy?

Answer 84

The amount of energy required to break 1 mole of a type of bond in a molecule in the gas phase.

Question 85

What is it important to remember when defining bond enthalpy?

Answer 85

The molecules are in the gas phase.

Question 86

Are bond enthalpies positive or negative?

Answer 86

Positive, because breaking bonds is always an endothermic process.

Question 87

What is mean bond enthalpy?

Answer 87

The energy needed to break one mole of bonds in the gas phase, averaged over many different compounds.

Question 88

Is the bond enthalpy of a certain bond always the same?

Answer 88

No, it varies between compounds, so it is usually quoted as a mean bond enthalpy in data books.

Question 89

Compare the bond enthalpy of the two O-H bonds in water?

Answer 89

• First OH -> +492 kJ/mol
• Second OH -> +428 kJ/mol

The second bond is easier to break because of the extra electron repulsion.

Question 90

What is the equation for the enthalpy change of a reaction in terms of bond enthalpies?

Answer 90

Enthalpy change = Sum of bond enthalpies of reactants - Sum of bond enthalpies of products

(Enthalpy change = Energy absorbed to break bonds - Energy realeased in making bonds)

Question 91

N2 (g) + 3H2 (g) -> 2NH3 (g)

Work out the overall enthalpy change given that:
N≡N -> 945 kJ/mol
H-H -> 436 kJ/mol
N-H -> 391 kJ/mol

Answer 91

Bonds broken:
945 + (3 x 436) = 2253 kJ/mol
Bonds formed:
6 x 391 = 2346 kJ/mol
Enthalpy change:
ΔH = 2253 - 2346 = -93 kJ/mol

Question 92

In enthalpy calculation using bond enthalpies, why might there be some variation between the calculated value and the actual value?

Answer 92

1) The specific bond enthalpies of the molecules may be slightly different from the mean values given
2) In an experiment, the molecules may not be in their gaseous state, so the bond enthalpies are different

Question 93

N2 (g) + 3F2 (g) -> 2NF3 (g)

The enthalpy change of the reaction is -264.2 kJ/mol. Find the mean N-F bond enthalpy, given that:
N≡N -> 945 kJ/mol
F-F -> 158 kJ/mol

Answer 93

Bonds broken:
945 + (3 x 158) = 1419 kJ/mol
Bonds formed:
6 x N-F
Enthalpy change:
-264.2 = (945 + 474) - (6 x N-F)
N-F = [945 + 474 -(-264.2)] / 6 = +281 kJ/mol