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Energy, Rates, and Equilibrium

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Kinetic: due to motion of the object KE = 1/2 mv2 (m = mass, v = velocity) ... there is a direct relationship between concentration and reaction rate; ... – PowerPoint PPT presentation

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Title: Energy, Rates, and Equilibrium


1
Chapter 7
  • Energy, Rates, and Equilibrium

2
Energy
  • The capacity to do work

3
The Two Types of Energy
  • Potential due to position or composition One
    must compare what can be made from what you have
    in order to determine the potential.
  • Kinetic due to motion of the object
  • KE 1/2 mv2
  • (m mass, v velocity)

4
Food Calories
  • Food is stored chemical potential energy.
  • Energy is produced by reacting the food we eat
    with oxygen.
  • Some of the energy can be used to do work!

5
Exothermic Reactions
  • Some reactions give off heat.
  • Once the magnesium begins to burn, the heat given
    off makes more magnesium burn.
  • Link to Magnesium burning

6
Endothermic Reactions
  • Some reactions use heat during a reaction.
  • The hot water supplies the heat needed to sublime
    the solid carbon dioxide into gaseous carbon
    dioxide.
  • Link to Sublimation Video

7
Energy
  • Potential - Stored energy
  • It is not the energy in the bonds of the compound
    you have in your hands that makes it have
    potential energy.
  • It is the energy of the new bonds that are formed
    in a chemical reaction that makes for the
    potential energy in the reactants.

8
Energy Diagrams
  • It is the difference which determines the
    potential

9
Covalent Bond Strength
  • Most simply, the strength of a bond is measured
    by determining how much energy is required to
    break the bond.
  • This is the bond enthalpy.
  • The bond enthalpy for a ClCl bond is measured to
    be 242 kJ/mol.

10
The enthalpy change required to break a
particular bond in one mole of gaseous molecules
is the bond energy.
Bond Energy
9.10
11
Average Bond Enthalpies
  • This table lists the average bond enthalpies
    (kJ/mol) for many different types of bonds.
  • Average bond enthalpies are positive, because
    bond breaking is an endothermic process.

12
Energy
  • The energy required to break a bond is equal to
    the energy liberated when making a bond.
  • LAW of conservation of energy
  • Neither created nor destroyed during physical or
    chemical changes

13
Enthalpies of Reaction
  • Compare the bond enthalpies of bonds broken to
    the bond enthalpies of the new bonds formed.

?Hrxn ?(bonds broken)??(bonds formed)
14
Enthalpies of Reaction
  • CH4(g) Cl2(g) ??? CH3Cl(g) HCl(g)
  • In this example,
  • One CH bond and one ClCl bond are broken
  • one CCl and one HCl bond are formed.
  • So,
  • ?Hrxn D(CH) D(ClCl) ? D(CCl) D(HCl)
  • (413 kJ) (242 kJ) ? (328 kJ) (431 kJ)
  • (655 kJ) ? (759 kJ)
  • ?104 kJ

15
Free Energy, Enthalpy, Entropy
  • DH Total heat energy of a system at constant
    pressure.
  • Not all of this can be used to do work.
  • DG That part which can do work
  • DS x T That part which cannot do work.
  • DG DH - T DS
  • If DG is favorable, the process will proceed and
    work can be extracted from the process.
  • If DG is unfavorable, work must be continually
    added to make the process proceed.

16
Reaction Rates
  • Even if energy can be extracted from a system,
    how fast the energy is produced can make or break
    the process literally.
  • Example Atomic bomb vs. nuclear energy
  • Link

17
Reaction Rates
  • The rates of chemical reactions are affected by
    the following factors
  • molecular collisions
  • activation energy
  • nature of the reactants
  • concentration of the reactants
  • temperature
  • presence of a catalyst
  • On the following screens, we examine these
    factors one at a time

18
Molecular Collisions
  • two species must collide to react
  • calculations show that the rate things collide is
    far greater than the rate at which they react
  • Conclusion most collisions do not result in a
    reaction
  • a collision that does result in a reaction is
    called an effective collision
  • there are two main reasons why some collisions
    are effective and others are not
  • energy
  • orientation

19
Molecular Collisions
  • Activation energy the minimum energy required
    for a reaction to take place
  • energy is required for reactions to begin even if
    they give off energy during the process
  • this energy comes from collisions
  • if the collision energy is large, there is
    sufficient energy to break the necessary bonds,
    and reaction takes place
  • if the collision energy is too small, no reaction
    occurs

20
Molecular Collisions
  • Orientation at the time of collision
  • the colliding particles must be properly oriented
    for bond breaking and bond making
  • for example, to be an effective collision between
    H2O and HCl, the oxygen of H2O must collide with
    the H of HCl so that the new O-H bond can form
    and the H-Cl bond can break

21
Energy Diagrams
  • Energy diagram for an exothermic reaction

22
Energy Diagrams
  • The reaction of H2 and N2 to form ammonia is
    exothermic
  • in this reaction, six covalent bonds are broken
    and six new ones are formed
  • breaking a bond requires energy, and forming a
    bond releases energy
  • in this reaction, the energy released in making
    the six new bonds is greater than the energy
    required to break the six original bonds the
    reaction is exothermic

23
Energy Diagrams
  • Energy diagram for an endothermic reaction

24
Energy Diagrams
  • Transition state a maximum on an energy diagram
  • the transition state for the reaction between H2O
    and HCl probably looks like this, in which the
    new O-H bond is partially formed and the H-Cl
    bond is partially broken

25
Factors Affecting Rate
  • Nature of reactants
  • in general, reaction between ions in aqueous
    solution are very fast (activation energies are
    very low)
  • in general, reaction between covalent compounds,
    whether in water or another solvent, are slower
    (their activation energies are higher)
  • Concentration
  • in most cases, reaction rate increases when the
    concentration of either or both reactants
    increases
  • for many reactions, there is a direct
    relationship between concentration and reaction
    rate when concentration doubles the rate doubles

26
Factors Affecting Rate
  • Temperature
  • in virtually all reactions, rate increases as
    temperature increases
  • an approximate rule for many reactions is that
    for a 10C increase in temperature, the reaction
    rate doubles
  • when temperature increases, molecules move faster
    (have more kinetic energy), which means that they
    collide more frequently more frequent collisions
    mean higher reaction rates
  • not only do molecules move faster at higher
    temperatures, but the fraction of molecules with
    energy equal to or greater than the activation
    energy also increases

27
Factors Affecting Rate
  • The distribution of kinetic energies (molecular
    velocities) at two temperatures

28
Factors Affecting Rate
  • Catalyst a substance that increases the rate of
    a chemical reaction without itself being used up

29
Factors Affecting Rate
  • Many catalysts provide a surface on which
    reactants can meet
  • the reaction of ethylene with hydrogen is an
    exothermic reaction
  • if these two reagents are mixed, there is no
    visible reaction even over long periods of time
  • when they are mixed and shaken with a finely
    divided transition metal catalyst, such as Pd,
    Pt, or Ni, the reaction takes place readily at
    room temperature

30
Reversible Reactions
  • Reversible reaction one that can be made to go
    in either direction
  • if we mix CO and H2O in the gas phase at high
    temperature, CO2 and H2 are formed
  • we can also make the reaction take place the
    other way by mixing CO2 and H2
  • the reaction is reversible, and we can discuss
    both a forward reaction and a reverse reaction

31
Reversible Reactions
  • Equilibrium a dynamic state in which the rate of
    the forward reaction is equal to the rate of the
    reverse reaction
  • at equilibrium there is no change in
    concentration of either reactants or products
  • reaction, however, is still taking place
    reactants are still being converted to products
    and products to reactants, but the rates of the
    two reactions are equal

32
Equilibrium Constants
  • Equilibrium constant, K the product of the
    concentration of products of a chemical
    equilibrium divided by the concentration of
    reactants, each raised to the power equal to its
    coefficient in the balanced chemical equation
  • for the general reaction
  • the equilibrium constant is

33
Equilibrium Constants
  • Problem write the equilibrium constant for this
    reversible reaction
  • solution for this reaction, K is
  • note that no exponents are shown in this
    equilibrium constant by convention the exponent
    1 is not written

34
Equilibrium Constants
  • Problem when H2 and I2 react at 427C, the
    following equilibrium is reached
  • the equilibrium concentrations are I2 0.42
    mol/L, H2 0.025 mol/L, and HI 0.76 mol/L.
    Using these values, calculate the value of K
  • Solution
  • this K has no units because molarities cancel

35
Equilibrium and Rates
  • There is no relationship between a reaction rate
    and the value of K
  • reaction rate depends on the activation energy of
    the forward and reverse reactions these rates
    determine how fast equilibrium is reached but not
    its position
  • it is possible to have a large K and a slow rate
    at which equilibrium is reached
  • it is also possible to have a small K and a fast
    rate at which equilibrium is reached
  • it is also possible to have any combination of K
    and rate in between these two extremes

36
LeChateliers Principle
  • LeChateliers Principle when a stress is applied
    to a chemical system at equilibrium, the position
    of the equilibrium shifts in the direction to
    relieve the applied stress
  • We look at three types of stress that can be
    applied to a chemical equilibrium
  • addition of a reaction component
  • removal of a reaction component
  • change in temperature

37
LeChateliers Principle
  • Addition of a reaction component
  • suppose this reaction reaches equilibrium
  • suppose we now disturb the equilibrium by adding
    some acetic acid
  • the rate of the forward reaction increases and
    the concentrations of ethyl acetate and water
    increase
  • as this happens, the rate of the reverse reaction
    also increases
  • in time, the two rates will again become equal
    and a new equilibrium will be established

38
LeChateliers Principle
  • at the new equilibrium, the concentrations of
    reactants and products again become constant, but
    not the same as they were before the addition of
    acetic acid
  • the concentrations of ethyl acetate and water are
    now higher, and the concentration of ethanol is
    lower
  • the concentration of acetic acid is also higher,
    but not as high as it was immediately after we
    added the extra amount
  • the system has relieved the stress by increasing
    the components on the other side of the
    equilibrium
  • we say that the system has shifted to minimize
    the stress

39
LeChateliers Principle
  • Removal of a reaction component
  • removal of a component shifts the position of
    equilibrium to the side that produces more of the
    component that has been removed
  • suppose we remove ethyl acetate from this
    equilibrium
  • if ethyl acetate is removed, the position of
    equilibrium shifts to the right to produce more
    ethyl acetate and restore equilibrium
  • the effect of removing a component is the
    opposite of adding one

40
LeChateliers Principle
  • Problem when acid rain attacks marble (calcium
    carbonate), the following equilibrium can be
    written
  • how does the fact that CO2 is a gas influence
    the equilibrium?
  • Solution CO2 gas diffuses from the reaction
    site, and is removed from the equilibrium
    mixture the equilibrium shifts to the right and
    the marble continues to erode

41
LeChateliers Principle
  • Change in temperature
  • the effect of a change in temperature on an
    equilibrium depends on whether the forward
    reaction is exothermic or endothermic
  • consider this exothermic reaction
  • we can look on heat as a product of the reaction
  • adding heat (increasing the temperature) pushes
    the equilibrium to the left
  • removing heat (decreasing the temperature) pushes
    the equilibrium to the right

42
LeChateliers Principle
  • summary of the effects of change of temperature
    on a system in equilibrium

43
Chapter 7
End Chapter 7
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