Thermochemistry ch 16
Transcript of Thermochemistry ch 16
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Chapter 16: Reaction Energy
Another Incredible Chemistry
Extravaganza
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Thermochemistry- is the study of the transfer of energy as heat that accompany chemical
reactions and physical changes
Introductory Objectives
1. Explain the relationship between energy
and heat
2. Distinguish between heat capacity and
specific heat
Thermochemistry
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Energy
Energy - the capacity for doing work or supplying heat Chemical potential energy – the energy stored within
the structural units of chemical substances Different substances store different amounts of energy.
The kinds of atoms and their arrangement in the substance determine the amount of energy stored in the substance.
All energy in a process can be accounted for as work, stored energy, or heat
Law of Conservation of Energy – In any physical or chemical process, energy is neither created nor destroyed
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Heat (Q)
Heat – energy that transfers from one object to another because of a temperature difference between them
Cannot be detected by the senses or instruments
Only changes caused by heat can be detected!!!
Always flows from a warmer object to a cooler object
If two objects remain in contact, eventually the temperature of both objects will be the same
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Systems
System- part of the universe on which you focus your attention
Surroundings – include everything else in the universe
Universe – the system and the surroundings Example: Chemicals and water are in a
beaker. (Universe) Your system includes the chemicals and water. The beaker is the surrounding.
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Endothermic and Exothermic Reactions
Endothermic reaction: heat, Q, flows INTO a system (heat is absorbed); measured in joules (J) and is always a positive number.
Examples: melting of ice, evaporation of a puddle, sublimation of a mothball, heat used to cook food During endothermic phase changes, energy absorbed does not increase the temperature because the energy is being used to overcome attractions between particles. (Think of water and ice being able to simultaneously exist at 0°C)
These reactions willfeel COLD as heat
is drawn in
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What value of q is endothermic? Exothermic reaction: heat, Q, flows OUT of the system
(heat is given off), joules will be a negative number.
Examples: combustion of fossil fuels, cooling of skin as
perspiration evaporates, freezing of water
Bond-formation
These reactions feel HOTas heat is given off
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Heat vs. Temperature
Temperature: a measurement of the average
kinetic energy of the particles
Not the same thing as:
Heat: the energy transferred between
samples of matter because of a difference in
their temperatures.
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Think!
Suppose two identical candles are used to heat two samples of water. One sample is a cup of water; the other is 10 gallons of water in a drum.
1. How will the change in temperature of the samples compare?
Practically no change in the drum; a large increase in the cup
2. How will the amount of heat received by each container compare?
Both containers receive the same amount of heat
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Specific Heat Capacity
Q = m c ΔT
c = specific heat capacity (J/g٠K) Q = heat transferred (J) ΔT = change in temperature (K)
m = mass (g)Do problems 7-9 on page 552
J g (J/g٠K) K
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Specific Heat Capacity
Refer to Table 1 on page 533 Note that the temperature of water changes
less than the temperature of iron because the specific heat capacity of water is larger.
Specific heat capacity (specific heat) – the amount of heat it takes to raise the temperature of 1 g of the substance 1°C
Specific heat (c) is a measure of a substance to store heat. The specific heats of substances can be compared because the quantity (1 g) of matter involved is specified.
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Joule – the SI unit of heat and energy
A joule of heat raises the temperature of 1 g of pure water 0.2390 °C
1 J = 0.2390 cal 4.184 J = 1 cal Heat capacity – amount of heat needed to
increase the temperature of an object exactly
1°C Besides varying with mass, the heat capacity
of an object also depends on its chemical composition
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Heat Capacity and Specific Heat
calorie- the quantity of heat needed to raise the temperature of 1g of pure water 1°C
Calorie = 1000 calories (refers to energy in food)
1 Calorie = 1kilocalorie = 1000 calories “10g of sugar has 41 Calories” means that
10g of sugar releases 41 kilocalories of heat when completely burned to produce carbon dioxide and water
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Do Now
What is the relationship between a joule and a calorie? Calorie and a dietary calorie?
What is the difference between specific heat capacity and heat capacity? Give examples.
Explain how you could manipulate a liquid to bring it to a boil.
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Objectives
1. Construct equations that show the heat changes for chemical and physical processes
2. Calculate heat changes in chemical and physical processes
Think! A match won’t ignite unless you strike it and add the heat produced from friction. Is the burning of a match an endothermic reaction?
Is there a way to measure how much heat is released from a burning match?
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Answer to Think!
No; the reaction releases more energy in the form of heat and light than the amount of energy it absorbs to start.
Yes, but only indirectly. If the reaction were confined, then any temperature changes in the surroundings could be attributed to heat transfer from the reaction.
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Calorimetry
The accurate and precise measurement of heat change for chemical and physical processes
Need insulated container
1. Constant pressure calorimeter
2. Bomb calorimeter – constant volume
Measures the heat released from burning a compound; closed system: the mass of the system is constant
The heat released by the system is equal to the heat absorbed by its surroundings
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Enthalpy (H)
Heat changes for reactions carried out at
constant pressure, represented by a ΔH The text uses heat and enthalpy
interchangeably Heat change for a chemical reaction carried
out in aqueous solution:
Q = ΔH = mcΔT If Exothermic: ΔH = negative number
If Endothermic: ΔH = positive number
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Thermochemical Equations
An equation that includes the heat change Heat of reaction – the heat change for the
reaction exactly as it is written (Usually heat change at constant pressure)
CO(g) + 2H2(g) CH3OH(g) + 870.2 kJ
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Thermochemical Equations
An equation that includes the heat change Heat of reaction – the heat change for the
reaction exactly as it is written (Usually heat change at constant pressure)
Refer to page 303 The physical state of the reactants and products
must be given Standard conditions = 101.3 kPa (1atm) and 25
°C Amount of heat absorbed or released depends
on the number of moles
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Heat of Combustion
Heat of reaction for the complete burning of one mole of a substance
Refer to Table 11.4 on page 305 Like other heats of reaction, heats of
combustion are reported as the enthalpy changes when the reactions are carried out at 101.3 kPa of pressure and the reactants and products are in their physical states at 25 °C
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Objectives
Review sections 1 and 2 Explain question 16 on page 306 Know key terms and concepts Complete Interpreting Graphics Handout Classify, by type, the heat changes that occur
during melting, freezing, boiling, and condensing
Calculate heat changes that occur during melting, freezing, boiling, and condensing
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Review
Specific heat capacity (specific heat) – the amount of heat it takes to raise the temperature of 1 g of the substance 1°C C = q ÷ (m x ΔT)
Enthalpy (H) - Heat changes for reactions carried out at constant pressure
Heat change for a chemical reaction carried out in aqueous solution:
q = ΔH = m x C x ΔT Like other heats of reaction, heats of combustion are reported
as the enthalpy changes when the reactions are carried out at 101.3 kPa of pressure and the reactants and products are in their physical states at 25 °C
H is enthalpy or heat content ΔH represents a change in the heat content
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Low enthalpy High enthalpy
Molar heat of fusion (ΔHfus) – heat absorbed by one mole of a substance in melting from a solid to a liquid at a constant temperature
Molar heat of vaporization (ΔHvap) – the amount of heat necessary to vaporize one mole of a given liquid
Endothermic reactions
Fusion Vaporization(ice) (steam)(water)
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1) The amount of energy needed to change one mole
of any substance from solid to liquid is called the
molar heat of fusion.
2) The amount of energy needed to change one mole
any substance from liquid to gas is called the molar
heat of vaporization.
solid liquid gas
Fusion Vaporization
Solidification Condensation(ice) (steam)(water)
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Gibbs Free Energy
ΔG = ΔH – TΔS
+ΔG = will NOT happen naturally
-ΔG = will happen spontaneously
A reaction has ΔH = -76 kJ and
ΔS = -117J/K. Calculate ΔG for the reaction at 298.15 K. Is the reaction spontaneous?
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Energy is needed for change of phase!
solid liquid gas
Fusion Vaporization
Solidification Condensation(1 mol) (1 mol)(1 mol)
6.02 kJ 40.7 kJ
-6.02 kJ -40.7 kJ
Requires Energy
Gives Off Energy
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Molar heat of condensation (ΔHcond) – amount of heat released when one mole of vapor condenses
Molar heat of solidification (ΔHsolid) – the heat lost when one mole of a liquid solidifies at a constant temperature
Exothermic reactions
Solidification Condensation(ice) (steam)(water)
High EnthalpyLow Enthalpy
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Solid ----------------Liquid -------------------Vapor
+Fusion +Vaporization
-Solidification -Condensation < The molar heat of fusion is the heat absorbed
by one mole of a substance in melting from a solid to a liquid at a constant temperature. The heat lost when one mole of a liquid solidifies at a constant temperature is the molar heat of solidification. Because energy is conserved in all chemical and physical changes, the quantity of heat absorbed by the melting solid must equal the quantity of heat lost when the liquid solidifies.
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ΔHfus = - ΔHsolid
ΔHvap = - ΔHcond
Values are numerically the same, but the
values have different signs Fusion—endothermic—Vaporization (+) Solidification – exothermic—Condensation (-) The melting of one mole of ice at 0°C to one
mole of water at 0°C requires the absorption of 6.01 kJ of heat. What is the heat of fusion?
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Heat Values for Water The heat of fusion is 6.01 kJ/mol. The heat of solidification is -6.01 kJ/mol. Ice is commonly used to refrigerate
perishable foods. What happens to the temperature of the ice as it begins to melt?
The ice and the water are both at 0°C. The temperature will not rise above 0°C until all of the ice has melted.
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Problem Solving 1
How many grams of ice at 0°C and 101.3 kPa could be melted by the addition of 2.25 kJ of heat?
Standard conditions for ice exist. Use heat of fusion for water.
Grams for one mole (18g)/6.01 kJ = x/2.25 kJ Answer = 6.74 g ice
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Standard Heats of Formation
Standard heat of formation (ΔHf°) – the change in enthalpy that accompanies the formation of one mole of a compound from its elements with all substances at their standard states at 25°C
The standard heat of formation of a free element in its standard state is arbitrarily set at 0. (Includes diatomic molecules and graphite form of carbon)
Refer to Table A-14 on page 862
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Heat of Solution
ΔHsoln – heat change caused by the dissolution of one mole of a substance
Examples: (Refer to page 312) 1. Exothermic molar heat of solution:
sodium hydroxide dissolved in water, hot pack that mixes calcium chloride and water
2. Endothermic molar heat of solution: cold pack that allows water and ammonium nitrate to mix (Heat is released from the water and the temperature of the solution decreases.)
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Problem Solving 2
How much heat (in kJ) is absorbed when
24.8 g of H2O(l) at 100°C is converted to
steam at 100°C ? Use heat of vaporization for water. 24.8g/x = 18g/40.7 kJ Answer = 56.1 kJ
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Objectives
Apply Hess’s law of heat summation to find heat changes for chemical and physical processes
Calculate heat changes using standard heats of formation
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Hess’s Law of Heat Summation
Hess’s Law of Heat Summation – If you add two or more thermochemical equations to give a final equation, then you can also add the heats of reaction to give the final heat of reaction
Refer to question 32 on page 318 Reverse the second enthalpy change
(change sign to +) and cancel the oxygen Subtract +824.2 kJ from -1669.8 kJ Answer = -8.456 x 102 kJ
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Standard Heat of Reaction
The standard heat of reaction (ΔH°) is the difference between the standard heats of formation of all the reactants and products.
ΔH° = ΔHf° (products) - ΔHf° (reactants)
Refer to Sample Problem 15 on page 552.