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Title: Energy


1
Chapter 5
  • Energy
  • Thermodynamics
  • (rev. 0910)

2
Definition
  • Thermodynamics-
  • is the study of energy transformations.

3
Chemical Reactions
  • Chemical reactions involve not just the
    conversion of reactants into products, but also
    involve an energy change in the form of heatheat
    released as the result of a reaction, or heat
    absorbed as a reaction proceeds.
  • Energy changes accompany all chemical reactions
    and are due to rearranging of chemical bonding.

4
Making Bonds
  • Addition of energy is always a requirement for
    the breaking of bonds but the breaking of bonds
    in and of itself does not release energy.
  • Energy release occurs when new bonds are formed.

5
Bond Energy
  • If more energy is released when new bonds form
    than was required to break existing bonds, then
    the difference will result in an overall release
    of energy.
  • If, on the other hand, more energy is required to
    break existing bonds than is released when new
    bonds form, the
  • difference will result overall in energy being
    absorbed.

6
Overall Reaction Energy
  • Whether or not an overall reaction releases or
    requires energy depends upon the final balance
    between the breaking and forming of chemical
    bonds.

7
Energy is...
  • the ability to do work or produce heat.
  • conserved.
  • made of heat and work.
  • a state function. (Energy is a property that is
    determined by specifying the condition or state
    (e.g., temperature, pressure, etc.) of a system
    or substance.)
  • independent of the path, or how you get from
    point A to B.

8
Energy
  • While the total internal energy of a system (E)
    cannot be determined, changes in internal energy
    (E) can be determined.
  • The change in internal energy will be the amount
    of energy exchanged between a system and its
    surroundings during a physical or chemical
    change.
  • ? E E final - E initial

9
Definitions
  • Work is a force acting over a distance.
  • Heat is energy transferred between objects
    because of temperature difference. (Heat is not a
    property of a system or substance and is not a
    state function. Heat is a processthe transfer of
    energy from a warm to a cold object.)

10
System vs Surroundings
  • The Universe is divided into two halves.
  • system and the surroundings.
  • In a chemistry setting, a system includes all
    substances undergoing a physical or chemical
    change.
  • The surroundings would include everything else
    that is not part of the system.

11
Heat
  • Most commonly, energy is exchanged between a
    system and its surroundings in the form of heat.
  • Heat will be transferred between objects at
    different temperatures.
  • Thermochemistry is the study of thermal energy
    changes.

12
Exo vs Endo
  • Exothermic reactions release energy to the
    surroundings.
  • Endothermic reactions absorb energy from the
    surroundings.

13
Heat
Potential energy
14
Heat
Potential energy
15
Three Parts
  • Every energy measurement has three parts
  • A unit ( Joules of calories).
  • A number.
  • a sign to tell direction.
  • negative - exothermic
  • positive- endothermic

16
Surroundings
System
Energy
DE lt0
17
Surroundings
System
Energy
DE gt0
18
Same rules for heat and work
  • Heat given off is negative.
  • Heat absorbed is positive.
  • Work done by the system on the surroundings is
    negative.
  • Work done on the system by the surroundings is
    positive.

19
First Law of Thermodynamics
  • The energy of the universe is constant.
  • It is also called the
  • Law of conservation of energy.
  • q heat w work
  • In a chemical system, the energy exchanged
    between a system and its surroundings can be
  • accounted for by heat (q) and work (w).
  • DE q w
  • Take the systems point of view to decide signs.

20
Conservation of Energy
  • Energy exchanged between a system and its
    surroundings can be considered to off set one
    another.
  • The same amount of energy leaving a system will
    enter the surroundings (or vice versa), so the
    total amount of energy remains constant.

21
Metric Units
  • The SI (Metric System) unit for all forms of
    energy is the joule (J).

22
Heat and Work
  • DE q w
  • - q is exothermic -q -?H
  • q is endothermic
  • -w is done by the system
  • w is done on the system
  • Note
  • ?H stands for enthalpy which is the heat of
    reaction

23
Practice Problem
  • A gas absorbs 28.5 J of heat and then performs
    15.2 J of work. The change in internal
  • energy of the gas is
  • (a) 13.3 J
  • (b) - 13.3 J
  • (c) 43.7 J
  • (d) - 43.7 J
  • (e) none of the above

24
Answer
  • (b) E q w
  • 28.5 J - 15.2 J 13.3 J

25
Practice Problem
  • Which of the following statements correctly
    describes the signs of q and w for the following
    exothermic process at 1 atmosphere pressure and
    370 Kelvin?
  • H2O(g) ? H2O(l)
  • (a) q and w are both negative
  • (b) q is positive and w is negative
  • (c) q is negative and w is positive
  • (d) q and w are both positive
  • (e) q and w are both zero

26
Answer
  • (c). An exothermic indicates q is negative and
    the gas is condensing to a liquid so it is
    exerting less pressure on its surroundings
    indicating w is positive.

27
What is work?
  • Work is a force acting over a distance.
  • w F x Dd
  • P F/ area
  • d V/area
  • w (P x area) x D (V/area) PDV
  • Work can be calculated by multiplying pressure by
    the change in volume at constant pressure.
  • Use units of literatm or Latm

28
Pressure and Volume Work
  • Work refers to a force that moves an object over
    a distance.
  • Only pressure/volume work (i.e., the
    expansion/contraction of a gas) is of
    significance in chemical systems and only when
    there is an increase or decrease in the amount of
    gas present.

29
Work needs a sign
  • If the volume of a gas increases, the system has
    done work on the surroundings.
  • work is negative
  • w - PDV
  • Expanding work is negative.
  • Contracting, surroundings do work on the system W
    is positive.
  • 1 Latm 101.3 J

30
Example
  • When, in a chemical reaction, there are more
    moles of product gas compared to
  • reactant gas, the system can be thought of as
    performing work on its surroundings (making w lt
    0) because it is pushing back, or moving back
    the atmosphere to make room for the expanding
    gas.
  • When the reverse is true, w gt 0.

31
Compressing and Expanding Gases
  • Compressing gas
  • Work on the system is positive
  • Work is going into the system
  • Expanding gas
  • Work on the surroundings is negative
  • Work is leaving the system

32
Clarification Info
  • If the reaction is performed in a rigid
    container, there may be a change in pressure,
  • but if there is no change in volume, the
    atmosphere outside the container didnt move
    and without movement, no work is done by or on
    the system.
  • If there is no change in volume (V 0), then no
    work is done by or on the system (w 0) and the
    change in internal energy will be entirely be due
    to the heat involved ( ?E q).

33
Examples
  • What amount of work is done when 15 L of gas is
    expanded to 25 L at 2.4 atm pressure?
  • If 2.36 J of heat are absorbed by the gas above.
    what is the change in energy?
  • How much heat would it take to change the gas
    without changing the internal energy of the gas?

34
Enthalpy
  • The symbol for Enthalpy is H
  • H E PV (thats the definition)
  • at constant pressure.
  • DH DE PDV
  • the heat at constant pressure qp can be
    calculated from
  • DE qp w qp - PDV
  • qp DE P DV DH

35
DH DE PDV
  • Using DH DE PDV
  • the heat at constant pressure qp can be
    calculated from
  • DE qp w (if w - PDV then)
  • DE qp PDV (now rearrange)
  • qp DE P DV DH

36
Examples of Enthapy Changes
  • KOH(s) ? K(aq) OH-1 (aq)
    ?Hsolution - 57.8 kJ mol1
  • C3H8(g) 5O2(g) ? 3CO2(g) 4H2O(l)
    ?Hcombustion -2221kJ/mol
  • H2O(s) ? H2O(l)
    ?Hfusion 6.0 kJ/mol
  • Fe2O3(s) 2Al(s) ? Al2O3(s) 2Fe(s)
    ?Hreaction - 852 kJ/mol
  • Ca(s) O2(g) H2(g) ? Ca(OH)2(s)
    ?Hformation - 986 kJ/mol1

37
3 Methods
  • There are a variety of methods for calculating
    overall enthalpy changes that you should be
    familiar with.
  • The three most common are the
  • the use of Heats of Formation
  • Hesss Law
  • the use of Bond Energies

38
Heat of Reaction
  • To compare heats of reaction for different
    reactions, it is necessary to know the
    temperatures at which heats of reaction are
    measured and the physical states of the reactants
    and products.
  • Look in the Appendix of the textbook to find
    Standard Enthapy tables.

39
Standard Enthalpy of Formation
  • Measurements have been made and tables
    constructed of Standard Enthalpies of Formation
    with reactants in their standard states.
  • Use the symbol DHºf
  • Standard state is the most stable physical state
    of reactants at
  • 1 atmosphere pressure
  • specified temperatureusually 25 C
  • 1 M solutions
  • For solids which exist in more than one
    allotropic form, a specific allotrope must be
    specified.

40
?Hformation
  • It is important to recognize that the
    ?Hformation (abbreviated as ?Hf) is really just
    the heat of reaction for a chemical change
    involving the formation of a compound from its
    elements in
  • their standard states.

41
Standard Enthalpies of Formation
  • The standard heat of formation is the amount of
    heat needed to form 1 mole of a compound from its
    elements in their standard states.
  • See the table in the Appendix
  • Remember For an element the value is 0

42
Equation Practice
  • You need to be able to write the equation
    correctly before solving the problem.
  • Try
  • What is the equation for the formation of NO2 ?
    Try writing the equation.

43
Practice Answer
  • ½N2 (g) O2 (g) NO2 (g)
  • You must make one mole to meet the definition.

44
Since we can manipulate the equations
  • We can use heats of formation to figure out the
    heat of reaction.
  • Lets do it with this equation.
  • C2H5OH 3O2(g) 2CO2 3H2O
  • which leads us to this rule.

45
Hesss Law
  • Definition
  • When a reaction may be expressed as the algebraic
    sum of other reactions, the enthalpy change of
    the reaction is the algebraic sum of the enthalpy
    changes for the combined reactions.

46
Hess Law
  • Enthalpy is a state function.
  • It is independent of the path.
  • We can add equations to come up with the desired
    final product, and add the DH values.
  • Two rules to remember
  • If the reaction is reversed the sign of DH is
    changed
  • If the reaction is multiplied, so is DH

47
Enthalpy
  • As enthalpy is an extensive property, the
    magnitude of an enthalpy change for a chemical
    reaction depends upon the quantity of material
    that reacts.
  • This means
  • if the amount of reacting material in an
    exothermic reaction is doubled, twice the
    quantity of heat energy will be released.

48
For the oxidation of sulfur dioxide gas
  • SO2(g) ½O2(g) ? SO3(g)
  • ?H - 99 kJ/mol
  • Doubling the reaction results in
  • 2SO2(g) O2(g) ? 2SO3(g)
  • ?H - 198 kJ/mol
  • Notice that if you double the reaction, you must
    double the ?H value.

49
Sign Change of ?H
  • 2SO2(g) O2(g) ? 2SO3(g)
  • ?H - 198 kJ/mol
  • If the reaction is written as an endothermic
    reaction
  • 2SO3(g) ? 2SO2(g) O2(g)
  • ?H 198 kJ/mol

50
Tips for Hesss Law Problems
  • It is always a good idea to begin by looking for
    species that appear as reactants and products in
    the overall reaction.
  • This will provide a clue as to whether a reaction
    needs to be reversed or not.
  • Second, consider the coefficients of species that
    appear in the overall reaction.
  • This will help determine whether a reaction needs
    to be multiplied before the overall summation.

51
Example
  • C(s) O2(g) ? CO2(g) ?Hf - 394
    kJ/mol
  • 2H2(g) O2(g) ? 2H2O(l)
    ?Hf - 572 kJ/mol
  • CO2(g) 2H2O(l) ? CH4(g) 2O2(g) ?Hf 891
    kJ/mol
  • -------------------------------------------------
    ----
  • C(s) 2H2(g) ? CH4(g) ?Hf - 75
    kJ/mol

52
Hesss Law Example
Given
DHº 77.9kJ
DHº 495 kJ
DHº 435.9kJ
Calculate DHº for this reaction
53
Example
  • Given
    calculate DHº for this reaction

DHº -1300. kJ
DHº -394 kJ
DHº -286 kJ
54
Problems to Try
  • Try 12-3 Practice Problems

55
O2
NO2
-112 kJ
180 kJ
H (kJ)
NO2
68 kJ
N2
2O2
56
Calorimetry
  • Calorimetry is the study of the heat released or
    absorbed during physical and chemical reactions.
  • For a certain object, the amount of heat energy
    lost or gained is proportional to
  • the temperature change. The initial temperature
    and the final temperature in the calorimeter
  • are measured and the temperature difference is
    used to calculate the heat of reaction.

57
Equipment Calorimeter
  • There are two kinds of calorimeters
  • constant pressure
  • bomb

58
Calorimetry
  • Constant pressure calorimeter
  • (called a coffee cup calorimeter)
  • A coffee cup calorimeter measures DH.
  • The calorimeter can be an insulated cup, full of
    water.

59
Definitions
  • Heat capacity is the amount of energy required to
    raise the temperature of an object 1 kelvin or 1
    C.
  • Specific heat capacity is the heat capacity of
  • 1 gram of a substance.
  • Molar heat capacity is the heat capacity of
  • 1 mole of a substance.

60
Heat Capacity
  • Heat capacity is an extensive property, meaning
    it depends on the amount presenta large amount
    of a substance would require more heat to raise
    the temperature 1 K than a small amount of the
    same substance.

61
Specific Heat Capacity
  • Definition
  • The specific heat capacity of each substance is
    an intensive property which relates the heat
    capacity to the mass of the substance.

62
Specific Heat Capacity c
  • q mass x c x DT
  • Or written as
  • q mcDT
  • This is the main equation for calorimetry
    calculations
  • mass will be in grams
  • Units for c are J/g K or J/g C
  • The specific heat of water is 1 cal/g ºC

63
Molar Heat Capacity
  • Molar Heat Capacity is the heat capacity of 1
    mole of a substance.
  • molar heat capacity c/moles
  • heat molar heat x moles x DT
  • Remember that heat is shown as ?H
  • Make the units work and youve done the problem
    right.

64
Sign of q
  • If a process results in the sample losing heat
    energy, the loss in heat is designated as q is
    negative.
  • The temperature of the surroundings will
    increase during this exothermic process.
  • If the sample gains heat during the process,
    then q is positive. The temperature of the
  • surroundings will decrease during an endothermic
    process.
  • The amount of heat that an object gains or loses
    is directly proportional to the change in
  • temperature.

65
Examples
  • The specific heat of graphite is 0.71 J/gºC.
  • Calculate the energy needed to raise the
    temperature of 75 kg of graphite from 294 K to
    348 K.

66
Extra Problem
  • A 46.2 g sample of copper is heated to 95.4ºC and
    then placed in a calorimeter containing 75.0 g of
    water at 19.6ºC. The final temperature of both
    the water and the copper is 21.8ºC.
  • What is the specific heat of copper?

67
Calorimetry
  • Constant volume calorimeter is called a bomb
    calorimeter.
  • Material is put in a container with pure oxygen.
    Wires are used to start the combustion. The
    container is put into a container of water.
  • The heat capacity of the calorimeter is known and
    tested.
  • Since DV 0, PDV 0, DE q

68
Bomb Calorimeter
  • thermometer
  • stirrer
  • full of water
  • ignition wire
  • Steel bomb
  • sample

69
Properties
  • intensive properties are not related to the
    amount of substance.
  • Examples density, specific heat, temperature.
  • Extensive property - does depend on the amount of
    substance.
  • Examples Heat capacity, mass, heat from a
    reaction.

70
  • Collegeboard. (2007-2008). Professional
    Development workshop materials Special focus
    thermochemistry. http//apcentral.collegeboard.com
    /apc/public/repository/5886-3_Chemistry_pp.ii-88.p
    df
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