energy chap. 16. i.definitions a. energy energy is the ability to do work or produce heat...
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EnergyEnergyChap. 16Chap. 16Chap. 16Chap. 16
I.I. DefinitionsDefinitions
A.A. EnergyEnergy
Energy is the ability to do work or produce heat
I.I. DefinitionsDefinitions
A.A. EnergyEnergy
B.B. HeatHeat
Heat is energy moving from one place to another
I.I. DefinitionsDefinitions
Heat = EnergyHeat = Energy
For us, these terms will be used synonymously
A.A. EnergyEnergy
B.B. HeatHeat
C.C. TemperatureTemperature
A measure of the kinetic energy of the particles in a substance
I.I. DefinitionsDefinitions
A.A. EnergyEnergy
B.B. HeatHeat
C.C. TemperatureTemperature
D.D. EndothermicEndothermic
A description of a process that absorbs heat
I.I. DefinitionsDefinitions
A.A. EnergyEnergy
B.B. HeatHeat
C.C. TemperatureTemperature
D.D. EndothermicEndothermic
E.E. ExothermicExothermic
A description of a process that gives off heat
I.I. DefinitionsDefinitions
Energy of motion
II.II. Types of EnergyTypes of EnergyA.A. KineticKinetic
Moving objects
II.II. Types of EnergyTypes of EnergyA.A. KineticKinetic
1.1. MechanicalMechanical
Heat energy (moving particles)
II.II. Types of EnergyTypes of EnergyA.A. KineticKinetic
1.1. MechanicalMechanical
2.2. ThermalThermal
Stored energy
II.II. Types of EnergyTypes of EnergyA.A. KineticKinetic
B.B. PotentialPotential
Energy that can be released as gravity acts
II.II. Types of EnergyTypes of EnergyA.A. KineticKinetic
B.B. PotentialPotential1.1. GravitationalGravitational
Energy stored in chemical bonds
II.II. Types of EnergyTypes of EnergyA.A. KineticKinetic
B.B. PotentialPotential1.1. GravitationalGravitational
2.2. ChemicalChemical
Energy in the form of light
II.II. Types of EnergyTypes of EnergyA.A. KineticKinetic
B.B. PotentialPotential
C.C. RadiantRadiant
III.III. Measuring Heat (q)Measuring Heat (q)
A.A. UnitsUnitsIII.III. Measuring Heat (q)Measuring Heat (q)
SI unit of energy (work). Work done by applying one Newton force over one meter.
A.A. UnitsUnits1.1. joulejoule
III.III. Measuring Heat (q)Measuring Heat (q)
Energy required to heat one gram of water by 1° C.
A.A. UnitsUnits1.1. joulejoule
2.2. caloriecalorie
III.III. Measuring Heat (q)Measuring Heat (q)
A nutritional calorie. 1 Cal = 1000 cal
A.A. UnitsUnits1.1. joulejoule
2.2. caloriecalorie
3.3. CalorieCalorie
III.III. Measuring Heat (q)Measuring Heat (q)
Equivalent to calories
A.A. UnitsUnits1.1. joulejoule
2.2. caloriecalorie
3.3. CalorieCalorie
4.4. kilocaloriekilocalorie
III.III. Measuring Heat (q)Measuring Heat (q)
Equivalent to 1000 calories
A.A. UnitsUnits1.1. joulejoule
2.2. caloriecalorie
3.3. CalorieCalorie
4.4. kilocaloriekilocalorie
III.III. Measuring Heat (q)Measuring Heat (q)
Energy required to heat 1 lb. water by 1º F.
A.A. UnitsUnits1.1. joulejoule
2.2. caloriecalorie
3.3. CalorieCalorie
4.4. kilocaloriekilocalorie
5.5. BTUBTU
III.III. Measuring Heat (q)Measuring Heat (q)
Heat Unit ConversionsHeat Unit Conversions
1 cal = 4.184 J1 cal = 4.184 J
1000 cal = 1 Cal = 1 kcal1000 cal = 1 Cal = 1 kcal
Self Check – Ex. 1Self Check – Ex. 1
A reaction produces 3800 J A reaction produces 3800 J of heat. How many calories of heat. How many calories is this?is this?
Self Check – Ex. 2Self Check – Ex. 2
A can of soda contains 150 A can of soda contains 150 Calories. How many joules Calories. How many joules of energy is this?of energy is this?
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
Which has more heat?
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
Temp. = 35º C
Beaker #1 Beaker #2
Temp. = 65º C
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .1.1. Mass of materialMass of material
Which beaker could melt more Which beaker could melt more ice (which has more heat)?ice (which has more heat)?
Beaker #1 Beaker #2
T1 = 85º C
T2 = 85º C
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .1.1. Mass of materialMass of material
2.2. Type of materialType of material
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .
D.D. Specific HeatSpecific Heat
Amount of heat required to raise the temperature of 1 gram of substance by 1º C
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .
D.D. Specific HeatSpecific Heat1.1. Some material takes a lot of Some material takes a lot of
energy to raise its temperatureenergy to raise its temperature
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .
D.D. Specific HeatSpecific Heat1.1. Some material takes a lot of Some material takes a lot of
energy to raise its temperatureenergy to raise its temperature
2.2. Some material takes lessSome material takes less
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .
D.D. Specific HeatSpecific Heat1.1. Some material takes a lot of Some material takes a lot of
energy to raise its temperatureenergy to raise its temperature
2.2. Some material takes lessSome material takes less
3.3. For water it’s 1 calorie/g For water it’s 1 calorie/g ºCºC
Specific Heat TableSpecific Heat TableSubstanceSubstance Spec. Heat Spec. Heat (c)(c)
WaterWater 4.184 J/g ºC4.184 J/g ºC
AluminumAluminum 0.89 J/g ºC0.89 J/g ºC
IronIron 0.45 J/g ºC0.45 J/g ºC
CopperCopper 0.387 J/g ºC0.387 J/g ºC
SilverSilver 0.24 J/g ºC0.24 J/g ºC
GoldGold 0.129 J/g ºC0.129 J/g ºC
LeadLead 0.l28 J/g 0.l28 J/g ºCºC
III.III. Measuring Heat (q)Measuring Heat (q)A.A. UnitsUnits
B.B. Heat is related to temperatureHeat is related to temperature
C.C. Heat also depends on. . .Heat also depends on. . .
D.D. Specific HeatSpecific Heat
E.E. CalculationCalculation
q = m x c x ∆T
Self Check – Ex. 3Self Check – Ex. 3
How much heat must be How much heat must be applied to a 25 g chunk of applied to a 25 g chunk of ironiron to raise its temperature to raise its temperature by 100by 100ºC? (cºC? (cironiron = 0.45 J/g ºC) = 0.45 J/g ºC)
Self Check – Ex. 4Self Check – Ex. 4
How much heat must be How much heat must be applied to a 25 g sample of applied to a 25 g sample of waterwater to raise its temperature to raise its temperature by 100by 100ºC? (cºC? (cironiron = 4.18 J/g ºC) = 4.18 J/g ºC)
IV.IV. Bond EnergyBond Energy
This is endothermic
IV.IV. Bond EnergyBond EnergyA.A. When bonds are broken When bonds are broken
energy is energy is ..
This is endothermic
IV.IV. Bond EnergyBond EnergyA.A. When bonds are broken When bonds are broken
energy is energy is requiredrequired. (positive). (positive)
IV.IV. Bond EnergyBond EnergyA.A. When bonds are broken When bonds are broken
energy is energy is requiredrequired. (positive). (positive)
B.B. When bonds are formed When bonds are formed energy is energy is ..
IV.IV. Bond EnergyBond EnergyA.A. When bonds are broken When bonds are broken
energy is energy is requiredrequired. (positive). (positive)
B.B. When bonds are formed When bonds are formed energy is energy is releasedreleased. (negative). (negative)
This is exothermic
IV.IV. Bond EnergyBond EnergyA.A. When bonds are broken When bonds are broken
energy is energy is requiredrequired. (positive). (positive)
B.B. When bonds are formed When bonds are formed energy is energy is releasedreleased. (negative). (negative)
C.C. The sum of the bond energies The sum of the bond energies gives an estimate of the gives an estimate of the reaction energyreaction energy
IV.IV. Bond EnergyBond EnergyA.A. When bonds are broken When bonds are broken
energy is energy is requiredrequired. (positive). (positive)
B.B. When bonds are formed When bonds are formed energy is energy is releasedreleased. (negative). (negative)
C.C. The sum of the bond energies The sum of the bond energies gives an estimate of the gives an estimate of the reaction energyreaction energy1.1. Positive values = endothermicPositive values = endothermic
IV.IV. Bond EnergyBond EnergyA.A. When bonds are broken When bonds are broken
energy is energy is requiredrequired. (positive). (positive)
B.B. When bonds are formed When bonds are formed energy is energy is releasedreleased. (negative). (negative)
C.C. The sum of the bond energies The sum of the bond energies gives an estimate of the gives an estimate of the reaction energyreaction energy1.1. Positive values = endothermicPositive values = endothermic
2.2. Negative values = exothermicNegative values = exothermic
Self Check – Ex. 5Self Check – Ex. 5
Draw Lewis structures for Draw Lewis structures for each substance and calculate each substance and calculate the energy for the reaction the energy for the reaction below.below.
2CO + O2 2CO2
V.V. Enthalpy StoichiometryEnthalpy Stoichiometry
V.V. Enthalpy StoichiometryEnthalpy StoichiometryA.A. Enthalpy represented by Enthalpy represented by HH
and enthalpy change by and enthalpy change by ∆H∆H..
V.V. Enthalpy StoichiometryEnthalpy StoichiometryA.A. Enthalpy represented by Enthalpy represented by HH
and enthalpy change by and enthalpy change by ∆H∆H..
B.B. Enthalpy change for a reaction Enthalpy change for a reaction measured in measured in kJ/molkJ/mol..
V.V. Enthalpy StoichiometryEnthalpy StoichiometryA.A. Enthalpy represented by Enthalpy represented by HH
and enthalpy change by and enthalpy change by ∆H∆H..
B.B. Enthalpy change for a reaction Enthalpy change for a reaction measured in measured in kJ/molkJ/mol..
C.C. Exothermic reactions have Exothermic reactions have negative ∆H values. (+ negative ∆H values. (+ ∆H∆H for endothermic)
V.V. Enthalpy StoichiometryEnthalpy StoichiometryA.A. Enthalpy represented by Enthalpy represented by HH
and enthalpy change by and enthalpy change by ∆H∆H..
B.B. Enthalpy change for a reaction Enthalpy change for a reaction measured in measured in kJ/molkJ/mol..
C.C. Exothermic reactions have Exothermic reactions have negative ∆H values. (+ negative ∆H values. (+ ∆H∆H for endothermic)
D. Solving problems
Enthalpy StoichiometryEnthalpy Stoichiometry
Enthalpy StoichiometryEnthalpy Stoichiometry
1.1. Write a balanced equationWrite a balanced equation
Enthalpy StoichiometryEnthalpy Stoichiometry
1.1. Write a balanced equationWrite a balanced equation
2.2. Identify the units of the Identify the units of the unknownunknown
Enthalpy StoichiometryEnthalpy Stoichiometry
1.1. Write a balanced equationWrite a balanced equation
2.2. Identify the units of the Identify the units of the unknownunknown
3.3. Write the ‘given’Write the ‘given’
Enthalpy StoichiometryEnthalpy Stoichiometry
1.1. Write a balanced equationWrite a balanced equation
2.2. Identify the units of the Identify the units of the unknownunknown
3.3. Write the ‘given’Write the ‘given’
4.4. Fill in conversion factorsFill in conversion factors
V.V. Enthalpy StoichiometryEnthalpy StoichiometryA.A. Enthalpy represented by Enthalpy represented by HH
and enthalpy change by and enthalpy change by ∆H∆H..
B.B. Enthalpy change for a reaction Enthalpy change for a reaction measured in measured in kJ/molkJ/mol..
C.C. Exothermic reactions have Exothermic reactions have negative ∆H values. (+ negative ∆H values. (+ ∆H∆H for endothermic)
D. Solving problems1.1. Finding heatFinding heat
Self Check – Ex. 6Self Check – Ex. 6
How much heat is produced How much heat is produced when 75g of hydrogen is when 75g of hydrogen is burned in oxygen?burned in oxygen?
2H2 + O2 2H2O ∆H = - 484 kJ
V.V. Enthalpy StoichiometryEnthalpy StoichiometryA.A. Enthalpy represented by Enthalpy represented by HH
and enthalpy change by and enthalpy change by ∆H∆H..
B.B. Enthalpy change for a reaction Enthalpy change for a reaction measured in measured in kJ/molkJ/mol..
C.C. Exothermic reactions have Exothermic reactions have negative ∆H values. (+ negative ∆H values. (+ ∆H∆H for endothermic)
D. Solving problems1.1. Finding heatFinding heat
2.2. Finding massFinding mass
Self Check – Ex. 7Self Check – Ex. 7
What mass of hydrogen is What mass of hydrogen is required to produce 8500 kJ of required to produce 8500 kJ of energy?energy?
2H2 + O2 2H2O ∆H = - 484 kJ
VI.VI. Enthalpy CalorimetryEnthalpy Calorimetry
VI.VI. Enthalpy CalorimetryEnthalpy CalorimetryA.A. Calorimetry is the science of Calorimetry is the science of
heat measurementheat measurement
VI.VI. Enthalpy CalorimetryEnthalpy Calorimetry
1.1. Mass of water in calorimeterMass of water in calorimeter
A.A. Calorimetry is the science of Calorimetry is the science of heat measurementheat measurement
B.B. ΔH can be determined ΔH can be determined experimentally if you measure:experimentally if you measure:
VI.VI. Enthalpy CalorimetryEnthalpy Calorimetry
1.1. Mass of water in calorimeterMass of water in calorimeter
2.2. Initial temperatureInitial temperature
A.A. Calorimetry is the science of Calorimetry is the science of heat measurementheat measurement
B.B. ΔH can be determined ΔH can be determined experimentally if you measure:experimentally if you measure:
VI.VI. Enthalpy CalorimetryEnthalpy Calorimetry
1.1. Mass of water in calorimeterMass of water in calorimeter
2.2. Initial temperatureInitial temperature
3.3. Final temperatureFinal temperature
A.A. Calorimetry is the science of Calorimetry is the science of heat measurementheat measurement
B.B. ΔH can be determined ΔH can be determined experimentally if you measure:experimentally if you measure:
VI.VI. Enthalpy CalorimetryEnthalpy Calorimetry
1.1. Mass of water in calorimeterMass of water in calorimeter
2.2. Initial temperatureInitial temperature
3.3. Final temperatureFinal temperature
4.4. Mass of reactant usedMass of reactant used
A.A. Calorimetry is the science of Calorimetry is the science of heat measurementheat measurement
B.B. ΔH can be determined ΔH can be determined experimentally if you measure:experimentally if you measure:
Calculating Calculating ∆H∆H for rxn for rxn
1.1. Determine the units for your Determine the units for your answer.answer.
Calculating Calculating ∆H∆H for rxn for rxn
1.1. Determine the units for your Determine the units for your answer.answer.
2.2. Calculate the heat gained by the Calculate the heat gained by the water.water. QQ = = mc∆Tmc∆T
ccwaterwater = 4.18 J/g = 4.18 J/g ∙ ºC∙ ºC
Calculating Calculating ∆H∆H for rxn for rxn
1.1. Determine the units for your Determine the units for your answer.answer.
2.2. Calculate the heat gained by the Calculate the heat gained by the water.water.
3.3. Determine the heat lost by rxn.Determine the heat lost by rxn.
QQgainedgained = - Q = - Qlostlost
Calculating Calculating ∆H∆H for rxn for rxn
1.1. Determine the units for your Determine the units for your answer.answer.
2.2. Calculate the heat gained by the Calculate the heat gained by the water.water.
3.3. Determine the heat lost by rxn.Determine the heat lost by rxn.
4.4. Convert grams reactant into Convert grams reactant into moles reactant.moles reactant.
Calculating Calculating ∆H∆H for rxn for rxn
1.1. Determine the units for your Determine the units for your answer.answer.
2.2. Calculate the heat gained by the Calculate the heat gained by the water.water.
3.3. Determine the heat lost by rxn.Determine the heat lost by rxn.
4.4. Convert grams reactant into Convert grams reactant into moles reactant.moles reactant.
5.5. Divide heat lost (#3) by the Divide heat lost (#3) by the moles reactant (#4).moles reactant (#4).
Self Check – Ex. 8Self Check – Ex. 8
When a 10.0 g of NaOH is When a 10.0 g of NaOH is added to 200 g of water the added to 200 g of water the temperature goes from 18.2temperature goes from 18.2ºC ºC to 31.6ºC. What is to 31.6ºC. What is ∆H∆H for the for the reaction in kJ/mol?reaction in kJ/mol?
VII.VII. Hess’s LawHess’s Law
VII.VII. Hess’s LawHess’s LawA.A. When a series of equations are When a series of equations are
added together, their enthalpy added together, their enthalpy changes are also addedchanges are also added
2NO (g) + O2NO (g) + O22 (g) 2NO (g) 2NO22 (g) (g) ΔΔHH = -113 kJ= -113 kJ
Add these equationsAdd these equations
NN22 (g) + O (g) + O22 (g) 2NO (g) (g) 2NO (g) ΔΔHH = +181 kJ= +181 kJ
VII.VII. Hess’s LawHess’s LawA.A. When a series of equations are When a series of equations are
added together, their enthalpy added together, their enthalpy changes are also addedchanges are also added
B.B. Equations can be alteredEquations can be altered
VII.VII. Hess’s LawHess’s Law
1.1. If an equation is reversed . . .If an equation is reversed . . .
A.A. When a series of equations are When a series of equations are added together, their enthalpy added together, their enthalpy changes are also addedchanges are also added
B.B. Equations can be alteredEquations can be altered
COCO22 (g) CO (g) + ½ O (g) CO (g) + ½ O22 (g) (g) ΔΔHH = +283 kJ= +283 kJ
VII.VII. Hess’s LawHess’s Law
1.1. If an equation is reversed . . .If an equation is reversed . . .
2.2. If the coefficients are multiplied If the coefficients are multiplied by a factor . . .by a factor . . .
A.A. When a series of equations are When a series of equations are added together, their enthalpy added together, their enthalpy changes are also addedchanges are also added
B.B. Equations can be alteredEquations can be altered
* Using fractions is perfectly acceptable* Using fractions is perfectly acceptable
2C (g) + O2C (g) + O22 (g) CO (g) (g) CO (g) ΔΔHH = -111 kJ= -111 kJ XX ½ ½
Self Check – Ex. 9Self Check – Ex. 9
2H2H22 (g) + O (g) + O22 (g) 2H (g) 2H22O (O (ll) ) ΔΔHH = -572 kJ= -572 kJ
HH22 (g) + O (g) + O22 (g) 2H (g) 2H22OO22 ( (ll) ) ΔΔHH = -188 kJ= -188 kJ
2H2H22OO22 ( (ll) 2 H) 2 H22O (O (ll) + O) + O22 (g) (g) ΔΔHH = = ?? kJ kJ
Self Check – Ex. 10Self Check – Ex. 10
2H2H22 (g) + O (g) + O22 (g) 2H (g) 2H22O (g) O (g) ΔΔHH = -483.6 kJ= -483.6 kJ
3O3O22 (g) 2O (g) 2O33 (g) (g) ΔΔHH = +284 kJ= +284 kJ
3H3H22 (g) + O (g) + O33 (g) 3H (g) 3H22O (g) O (g) ΔΔHH = = ?? kJ kJ
VII.VII. Phase changes and Phase changes and heatheat
The End
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