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Thermochemistry

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Title: Thermochemistry


1
Thermochemistry
2
Heat in Chemical Reactions
  • Most chemical reactions involve energy to break
    or form bonds.
  • Thermochemistry In a chemical reaction, the
    study of changes in heat.
  • Heat The energy transferred from one object to
    another due to a difference in temperature.

3
How can I use the mole ratio in these problems?
  • Because the heats of chemical reactions are
    expressed in kJ/mol, these amounts can be used in
    stoichiometric problems as if it were a mole
    ratio!

4
Sample Problems
  • Calculate the heat required to melt 25.7 g of
    solid methanol at its melting point. The ?Hfus
    of methanol is 3.22 kJ/mol.

5
Sample Problem
  • What mass of methane must be burned in order to
    liberate 12.880 kJ of heat? The ?Hcomb of
    methane is -891 kJ/mol.

6
Heat and Enthalpy Changes
  • Enthalpy the heat content of a system at
    constant pressure
  • Represented as H
  • Depends on temperature, physical state, and
    composition
  • System must be at a constant pressure throughout
    the change

7
Enthalpy Change
  • ?H SHproducts SHreactants
  • Exothermic
  • Heat is released
  • ?H is NEGATIVE energy is released
  • Reaction feels warm
  • Extra energy shown on product side of equation
  • Endothermic
  • Heat is absorbed during a reaction
  • ?H is POSITIVE energy is absorbed
  • Reaction feels cold
  • Extra energy shown on reactant side of equation

8
Enthalpy Change Cont.
  • the amount of heat that rxn absorbs or releases
    depends on the conditions under which the rxn is
    carried out
  • -i.e. temp, pressure, physical states of
    reactants and products
  • Use 1 atmosphere as standard pressure and 25
    degrees C as temp.(room temp) for reporting
    enthalpy changes

9
Enthalpy Change Cont.
  • the standard state of a substance is its pure
    form at standard pressure
  • -pure elements must be present in its most stable
    form at standard pressure (standard state)
  • Standard enthalpy change- an enthalpy change that
    is measured when reactants in their standard
    states change to products in their standard
    states

10
Enthalpy Change Cont.
  • Denoted with a superscript 0 (?H degrees)
  • If the rxn occurs at temps other than 25 degrees
    C, the standard enthalpy change takes into
    account the heat involved in restoring the
    products to standard conditions after the
    reaction is complete
  • The amount of heat that is absorbed or released
    in a rxn depends on the of moles of reactants
    involved

11
Sample Problem
  • Calculate the ?H of the following reaction
  • 2SO2 (g) O2 (g) ? 2SO3 (g)

12
Hesss Law
  • States that the total enthalpy change for a
    chemical or physical change is the same whether
    it takes one step or several steps
  • If a series of rxns are added together the
    enthalpy change for the net rxn will be the sum
    of the enthalpy changes for the individual steps

13
Rules for Manipulating Reactions
  • If the coefficients of an equation are multiplied
    by a factor, the enthalpy change is multiplied by
    the same factor
  • If an equation is reversed, the sign of ?H is
    reversed also

14
Sample Problem
  • Use the thermochemical equations a and b to
    determine ?H for the decomposition of hydrogen
    peroxide.
  • 2H2O2(l) ? 2H2O(l) O2(g)
  • 2H2(g) O2(g) ? 2H2O (l) ?H -572 kJ
  • H2(g) O2(g) ? H2O2(l) ?H -188kJ

15
Sample Problem
  • Use reactions a and b to determine ?H for the
    following reaction
  • 2CO(g) 2NO(g) ? 2CO2(g) N2(g)
  • a. 2CO(g) O2(g) ? 2CO2(g) ?H -566.0 kJ
  • b. N2(g) O2(g) ? 2NO(g) ?H 180.6 kJ

16
Sample Problem
  • Use reactions a, b and c to determine ?H for the
    following reaction.
  • H2S(g) 4F2(g) ? 2HF(g) SF6(g)
  • a. 1/2 H2(g) 1/2 F2(g) ? HF(g) ?H -273 kJ
  • b. S(s) 3F2 (g)? SF6(g) ?H -1220 kJ
  • c. H2(g) S(s) ? H2S(g) ?H -21 kJ

17
Heat in Physical Changes
  • Changes in state are reversible processes that
    can be reversed by adjusting the temperature
  • Each change in state requires an energy transfer

18
Heat of Fusion
  • Symbol ?Hfus
  • Defined as heat necessary to convert one mole of
    a solid to a liquid at constant temperature
  • ?H mol substance x ?Hfus
  • Total heat change the number of moles of a
    substance x its heat of fusion
  • Heat of fusion is measured in kJ/mol

19
Heat of Solidification
  • Symbol ?Hsolid
  • Defined as heat necessary to convert one mole of
    liquid to a solid at a constant temperature
  • ?H mol substance x ?Hsolid
  • Total heat change the number of moles of a
    substance x its heat of solidification
  • Heat of solidification is measured in kJ/mol

20
Heat of Vaporization
  • Symbol ?Hvap
  • Defined as heat necessary to vaporize one mole
    of a given liquid
  • ?H mol substance x ?Hvap
  • Total heat change the number of moles of a
    substance x its heat of vaporization
  • Heat of vaporization is measured in kJ/mol

21
Heat of Condensation
  • Symbol ?Hcond
  • Defined as heat necessary to condense one mole
    of a given gas
  • ?H mol substance x ?Hcond
  • Total heat change the number of moles of a
    substance x its heat of condensation
  • Heat of condensation is measured in kJ/mol

22
Heat of Solution
  • Symbol ?Hsoln
  • Defined as heat necessary to dissolve one mole of
    a given substance
  • ?H mol substance x ?Hsoln
  • Total heat change the number of moles of a
    substance x its heat of solution
  • Heat of solution is measured in kJ/mol

23
Heat of Formation
  • Symbol ?Hf
  • Defined as heat necessary to form one mole of a
    compound from its elements
  • ?H mol substance x ?Hf
  • Total heat change the number of moles of a
    substance x its heat of formation
  • Heat of formation is measured in kJ/mol

24
Specific Heat
  • Relates temperature changes to heat changes
  • Defined as the amount of heat energy required to
    increase the temperature of one gram of a
    substance by one degree Celsius
  • Specific heat -Varies if pressure and temperature
    are not kept constant
  • A physical property
  • Varies depending on the substance
  • Symbol is Cp, units are J/gC

25
Specific Heat
  • Must be measured!
  • Substances with low specific heats require less
    energy to feel hot than those with high specific
    heats
  • Specific heat can be used to calculate changes in
    heat

26
Substance Specific Heat J/gC
Water (liquid) 4.184
Water (solid) 2.03
Water (steam) 2.01
Ethanol (liquid) 2.44
Aluminum (solid) 0.897
Granite (solid) 0.803
Iron (solid) 0.449
Lead (solid) 0.129
Silver (solid) 0.235
Gold (solid) 0.129
Copper (solid) 0.385
27
Heat Calculations
  • Change in heat of a substance can be calculated
    using the following equation
  • q m?TCp
  • q change in heat
  • m mass of the substance
  • ?T change in temperature of the substance
  • Cp specific heat of the substance

28
Total Energy Changes
  • The amount of heat (q) involved in a reaction is
    positive () if the sample warms up. The sample
    is gaining heat.
  • The amount of heat (q) involved in a reaction is
    negative (-) if the sample cools off. The sample
    is releasing, or losing, heat.

29
Specific Heat Problems
  • Use the sheet which has the chart on it to find
    the specific heat of the element or substance in
    the problem
  • Solve using algebra and the equation
  • q m?TCp

30
Sample Problems
If the temperature of 34.4 g of ethanol increases
from 25.0 ?C to 78.8 ?C, how much heat has been
absorbed by the ethanol? The specific heat of
ethanol is 2.44 J/(g??C)
31
Heat in a Chemical Reaction
  • Energy can be converted into other forms
  • Measures of changes in heat energy can be made in
    a calorimeter
  • Changes in heat energy can be used to calculate
    specific heat
  • These heats refer to the total flow of energy
    during a chemical change

32
Sample Problems
A 4.50 g nugget of pure gold absorbed 276 J of
heat. What was the final temperature of the gold
if the initial temperature was 25 ?C ? The
specific heat of gold is 0.129 J/(g??C).
33
Sample Problems
A 155-g sample of an unknown substance was heated
from 25.0?C to 40.0 ?C. In the process, the
substance absorbed 5696 J of energy. What is the
specific heat of the substance?
34
Calorimeter Questions
  • Transfer of heat is measured by measuring the
    difference in temperature transferred to water
    from an object
  • Specific heat of water (4.184 J/gC) and its mass
    is used to solve the problem.

35
Sample Problem
  • A piece of metal is placed in a calorimeter, and
    causes the 335 g of water to increase in
    temperature from 21.0C to 50.1C. What is the
    amount of energy released by the piece of metal?

36
Activation Energy
  • Defined as the minimum amount of energy that must
    be supplied to a system to start a chemical
    change.
  • Endothermic reactions must have a source from
    which to draw their energy (usually their
    surroundings)

37
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38
Spontaneity
  • Spontaneous change a change that proceeds on
    its own, without any outside intervention
  • Occurs primarily in one direction
  • Does not mean the reaction will occur quickly

39
Spontaneity
  • Some can occur when a small amount of energy is
    added to the system
  • Some can be reversed if conditions change
  • The more energy released, the lower enthalpy is
    and therefore the more likely the reaction will
    be spontaneous

40
Entropy and Stability
  • Entropy (S) a measure of the randomness or
    disorder of the system
  • The tendency of nature is toward more disorder
  • Its effects increase with temperature
  • Measured in units of J/K

41
Entropy
  • ?S Sproducts Sreactants
  • If entropy of a system increases during a
    reaction or process, Sproducts ? Sreactants and
    ?S is positive
  • If entropy of a system decreases,
    Sproducts lt Sreactants and ?S is negative

42
Entropy
  • When a solid turns to a liquid and a liquid to a
    gas, entropy increases (?S ? 0)
  • When a gas dissolves in a liquid, entropy
    decreases (?S ? 0)

43
Sample Problem
  • What is the entropy change for the single
    replacement reaction between sodium chloride and
    fluorine? SNaF 51.5 J/mol K

44
Sample Problem
  • What is the change in entropy for the
    decomposition of potassium chlorate? SKClO3(s)
    143.7 J/mol K

45
Gibbs Free Energy
  • Spontaneous rxns release energy that can perform
    work
  • Free energy change represents the maximum work
    that a spontaneous rxn can perform
  • Two ways to calculate Gibbs Free Energy
  • ?G ?Gproducts - ?Greactants
  • ?G ?H-T?S

46
Gibbs Free Energy Cont.
  • If ?G is negative the rxn is spontaneous
  • If ?G is positive the rxn is not spontaneous and
    requires sustained input of energy to make it
    occur
  • If ?G0 the rxn is at equilibrium
  • Exothermic rxns in which the products are more
    disordered than its reactants, ?G is always
    negative-regardless of temp

47
Gibbs Free Energy Cont.
  • Endothermic rxns in which the products are more
    ordered than its reactants, ?G is always
    positive- regardless of temp
  • ?G for a nonspontaneous rxn is the minimum amount
    of work that must be performed by an external
    source to make the rxn occur

48
  • Ex. Calculate the free energy change for the
    following rxn.
  • Determine if the reaction will be spontaneous or
    not.
  • C(s) 2H2(g) ? CH4(g)
  • ?S-80.7 J/mol K ?H -75.0k J/mol T298K
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