The Molecular Nature of Matter and Change
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Transcript of The Molecular Nature of Matter and Change
The Molecular Nature of Matter and Change
Lecture PowerPoint Chemistry The Molecular Nature of Matter and
Change Sixth Edition Martin S. Silberberg Copyright The McGraw-Hill
Companies, Inc. Permission required for reproduction or display.
Chapter 20 Thermodynamics:Entropy, Free Energy, and the Direction
of Chemical Reactions Thermodynamics:Entropy, Free Energy, and the
Direction of Chemical Reactions
20.1The Second Law of Thermodynamics:Predicting Spontaneous Change
20.2Calculating Entropy Change of a Reaction 20.3Entropy, Free
Energy, and Work 20.4Free Energy, Equilibrium, and Reaction
Direction Spontaneous Change A spontaneous change is one that
occurs without a continuous input of energy from outside the
system. All chemical processes require energy (activation energy)
to take place, but once a spontaneous process has begun, no further
input of energy is needed. A nonspontaneous change occurs only if
the surroundings continuously supply energy to the system. If a
change is spontaneous in one direction, it will be nonspontaneous
in the reverse direction. The First Law of Thermodynamics Does Not
Predict Spontaneous Change
Energy is conserved. It is neither created nor destroyed, but is
transferred in the form of heat and/or work. DE = q + w The total
energy of the universe is constant: DEsys = -DEsurr or DEsys +
DEsurr = DEuniv = 0 The law of conservation of energy applies to
all changes, and does not allow us to predict the direction of a
spontaneous change. DH Does Not Predict Spontaneous Change
A spontaneous change may be exothermic or endothermic. Spontaneous
exothermic processes include: freezing and condensation at low
temperatures, combustion reactions, oxidation of iron and other
metals. Spontaneous endothermic processes include: melting and
vaporization at higher temperatures, dissolving of most soluble
salts. The sign of DH does not by itself predict the direction of a
spontaneous change. A spontaneous endothermic chemical
reaction.
Figure 20.1 A spontaneous endothermic chemical reaction. Ba(OH)2
8H2O(s) + 2NH4NO3(s) Ba2+(aq) + 2NO3-(aq) + 2NH3(aq) + 10H2O(l)
DHrxn = kJ water This reaction occurs spontaneously when the solids
are mixed. The reaction mixture absorbs heat from the surroundings
so quickly that the beaker freezes to a wet block. Freedom of
Particle Motion
All spontaneous endothermic processes result in an increase in the
freedom of motion of the particles in the system. solid liquid gas
crystalline solid + liquid ions in solution less freedom of
particle motion more freedom of particle motion localized energy of
motion dispersed energy of motion A change in the freedom of motion
of particles in a system is a key factor affecting the direction of
a spontaneous process. Microstates and Dispersal of Energy
Just as the electronic energy levels within an atom are quantized,
a system of particles also has different allowed energy states.
Each quantized energy state for a system of particles is called a
microstate. At any instant, the total energy of the system is
dispersed throughout one microstate. At a given set of conditions,
each microstate has the same total energy as any other. Each
microstate is therefore equally likely. The larger the number of
possible microstates, the larger the number of ways in which a
system can disperse its energy. Entropy The number of microstates
(W) in a system is related to the entropy (S) of the system. S = k
lnW A system with fewer microstates has lower entropy. A system
with more microstates has higher entropy. All spontaneous
endothermic processes exhibit an increase in entropy. Entropy, like
enthalpy, is a state function and is therefore independent of the
path taken between the final and initial states. Figure 20.2
Spontaneous expansion of a gas. When the stopcock is opened, the
gas spontaneously expands to fill both flasks. Increasing the
volume increases the number of translational energy levels the
particles can occupy. The number of microstates and the entropy
increases. Figure 20.3 The entropy increase due to the expansion of
a gas. Opening the stopcock increases the number of possible energy
levels, which are closer together on average. More distributions of
particles are possible. Expansion of a gas and the increase in
number of microstates.
Figure 20.4 Expansion of a gas and the increase in number of
microstates. When the stopcock opens, the number of microstates is
2n, where n is the number of particles. DS for a Reversible
Process
qrev T A reversible process is one that occurs in such tiny
increments that the system remains at equilibrium, and the
direction of the change can be reversed by an infinitesimal
reversal of conditions. Figure 20.5 Simulating a reversible
process. A sample of Ne gas is confined to a volume of 1 L by the
pressure of a beaker of sand on the piston. We remove one grain of
sand (an infinitesimal decrease in pressure), causing the gas to
expand a tiny amount. The gas does work on its surroundings,
absorbing a tiny increment of heat, q, from the heat reservoir.
This simulates a reversible process, since it can be reversed by
replacing the grain of sand. The Second Law of Thermodynamics
The sign of S for a reaction does not, by itself, predict the
direction of a spontaneous reaction. If we consider both the system
and the surroundings, we find that all real processes occur
spontaneously in the direction that increases the entropy of the
universe. For a process to be spontaneous, a decrease in the
entropy of the system must be offset by a larger increase in the
entropy of the surroundings. DSuniv = DSsys + DSsurr > 0
Comparing Energy and Entropy
The total energy of the universe remains constant. DEsys + DEsurr
=DEuniv = 0 DH is often used to approximateDE. For enthalpy there
is no zero point; we can only measure changes in enthalpy. The
total entropy of the universe increases. DSuniv =DSsys +DSsurr >
0 For entropy there is a zero point, and we can determine absolute
entropy values. The Third Law of Thermodynamics
A perfect crystal has zero entropy at absolute zero. Ssys = 0 at 0
K A perfect crystal has flawless alignment of all its particles. At
absolute zero, the particles have minimum energy, so there is only
one microstate. S = k lnW = k ln 1 = 0 To find the entropy of a
substance at a given temperature, we cool it as close to 0 K as
possible. We then heat in small increments, measure q and T, and
calculate DS for each increment. The sum of these DS values gives
the absolute entropy at the temperature of interest. Standard Molar
Entropies
S is the standard molar entropy of a substance, measured for a
substance in its standard state in units of J/molK. The conventions
for defining a standard state include: 1 atm for gases 1 M for
solutions, and the pure substance in its most stable form for
solids and liquids. Factors Affecting Entropy
Entropy depends on temperature. For any substance, S increases as
temperature increases. Entropy depends on the physical state of a
substance. S increases as the phase changes from solid to liquid to
gas. The formation of a solution affects entropy. Entropy is
related to atomic size and molecularcomplexity. Remember to compare
substances in the same physical state. Figure 20.6A Visualizing the
effect of temperature on entropy. Computer simulations show each
particle in a crystal moving about its lattice position. Adding
heat increases T and the total energy, so the particles have
greater freedom of motion, and their energy is more dispersed. S
therefore increases. Figure 20.6B Visualizing the effect of
temperature on entropy. At any T, there is a range of occupied
energy levels and therefore a certain number of microstates. Adding
heat increases the total energy (area under the curve), so the
range of occupied energy levels becomes greater, as does the number
of microstates. Figure 20.6C Visualizing the effect of temperature
on entropy. A system of 21 particles occupy energy levels (lines)
in a box whose height represents the total energy. When heat is
added, the total energy increases and becomes more dispersed, so S
increases. Figure 20.7 The increase in entropy during phase changes
from solid to liquid to gas. The entropy change accompanying the
dissolution of a salt.
Figure 20.8 The entropy change accompanying the dissolution of a
salt. Copyright The McGraw-Hill Companies, Inc. Permission required
for reproduction or display. pure solid MIX pure liquid solution
The entropy of a salt solution is usually greater than that of the
solid and of water, but it is affected by the organization of the
water molecules around each ion. Figure 20.9 The small increase in
entropy when ethanol dissolves in water. Ethanol (A) and water (B)
each have many H bonds between their own molecules. In solution (C)
they form H bonds to each other, so their freedom of motion does
not change significantly. Figure 20.10 The entropy of a gas
dissolved in a liquid. Entropy and Atomic Size
S is higher for larger atoms or molecules of the same type. Li Na K
Rb Cs Atomic radius (pm) 152 186 227 248 265 Molar mass (g/mol)
6.941 22.99 39.10 85.47 132.9 S(s) 29.1 51.4 64.7 69.5 85.2 HF HCl
HBr HI Molar mass (g/mol) 20.01 36.46 80.91 127.9 S(s) 173.7 186.8
198.6 206.3 Entropy and Structure For allotropes, S is higher in
the form that allows the atoms more freedom of motion. S of
graphite is 5.69 J/molK, whereas S of diamond is 2.44 J/molK. For
compounds, S increases with chemical complexity. NaCl AlCl3 P4O10
NO NO2 N2O4 S(s) 72.1 167 229 S(g) 211 240 304 These trends only
hold for substances in the same physical state. Figure 20.11
Entropy, vibrational motion, and molecular complexity. Sample
Problem 20.1 Predicting Relative Entropy Values PROBLEM: Choose the
member with the higher entropy in each of thefollowing pairs, and
justify your choice [assume constanttemperature, except in part
(e)]: (a)1 mol of SO2(g) or 1 mol of SO3(g) (b)1 mol of CO2(s) or 1
mol of CO2(g) (c)3 mol of O2(g) or 2 mol of O3(g) (d)1 mol of
KBr(s) or 1 mol of KBr(aq) (e) seawater at 2C or at 23C (f)1 mol of
CF4(g) or 1 mol of CCl4(g) PLAN: In general, particles with more
freedom of motion have more microstates in which to disperse their
kinetic energy, so they have higher entropy. Raising the
temperature or having more particles increases entropy. Sample
Problem 20.1 SOLUTION: (a)1 mol of SO3(g).For equal numbers of
moles of substances with the same types of atoms in the same
physical state, the more atoms in the molecule the higher the
entropy. (b)1 mol of CO2(g).For a given substance, entropy
increases as the phase changes from solid to liquid to gas. (c)3
mol of O2(g).The two samples contain the same number of oxygen
atoms but different numbers of molecules. Although each O3 molecule
is more complex than each O2 molecule, the greater number of
molecules dominates because there are many more microstates
possible for 3 mol of particles than for 2. Sample Problem 20.1
(d)1 mol of KBr(aq).The two samples have the same number of ions,
but their motion is more limited and their energy less dispersed in
the solid than in the solution. An ionic substance in solution
usually has a higher entropy than the solid. (e)Seawater at 23C.
Entropy increases with rising temperature. (f)1 mol of CCl4(g).For
similar compounds, entropy increases with molar mass. Entropy
Changes in the System
The standard entropy of reaction, DSrxn, is the entropy change that
occurs when all reactants and products are in their standard
states. DSrxn = SmSproducts - SnSreactants where m and n are the
amounts (mol) of products and reactants, given by the coefficients
in the balanced equation. Predicting the Sign of DSrxn
We can often predict the sign of DSrxn for processes that involve a
change in the number of moles of gas. DSrxn is positive if the
amount of gas increases; e.g., H2(g) + I2(s) 2HI(g). DSrxn is
negative if the amount of gas decreases; e.g., DS is likely to be
positive if a new structure forms thathas more freedom of motion.
N2(g) + 3H2(g) NH3(g) Sample Problem 20.2 Calculating the Standard
Entropy of Reaction, DSrxn PROBLEM: Predict the sign ofDSrxn and
calculate its value for the combustion of 1 mol of propane at 25C.
C3H8(g) + 5O2(g) 3CO2(g) + 4H2O(l) PLAN: From the change in the
number of moles of gas (6 mol yields 3 mol), the entropy should
decrease (DSrxn < 0). To find DSrxn, we apply Equation 20.4,
using the S values from Appendix B. SOLUTION: Srxn = [(3 mol CO2)(S
of CO2) + (4 mol H2O)(S of H2O)] - [(1 mol C3H8)(S of C3H8) + (5
mol O2)(S of O2) = [(3mol)(213.7J/Kmol) + (4 mol)(69.9J/Kmol)]
[(1mol)(269.9 J/Kmol) + (5 mol)(205.0 J/Kmol) = -374 J/K Entropy
Changes in the Surroundings
A decrease in the entropy of the system is outweighed by an
increase in the entropy of the surroundings. The surroundings
function as a heat source or heat sink. In an exothermic process,
the surroundings absorbs the heat released by the system, and Ssurr
increases. qsys < 0;qsurr > 0 and DSsurr > 0 In an
endothermic process, the surroundings provides the heat absorbed by
the system, and Ssurr decreases. qsys > 0;qsurr < 0 and
DSsurr < 0 Temperature at which Heat is Transferred
Since entropy depends on temperature, DSsurr is also affected by
the temperature at which heat is transferred. For any reaction,
qsys = -qsurr. The heat transferred is specific for the reaction
and is the same regardless of the temperature of the surroundings.
The impact on the surroundings is larger when the surroundings are
at lower temperature, because there is a greater relative change in
Ssurr. DSsurr = - DHsys T for a process at constant P. DSsurr = -
qsys T Sample Problem 20.3 Determining Reaction Spontaneity
PROBLEM: At 298 K, the formation of ammonia has a negative DSsys;
N2(g) + 3H2(g) 2NH3(g); DSsys = -197 J/K Calculate DSuniv, and
state whether the reaction occursspontaneously at this temperature.
PLAN: For the reaction to occur spontaneously, DSuniv > 0, so
DSsurr must be greater than +197 J/K. To find DSsurr we need DHsys,
which is the same as DHrxn. We use the standard enthalpy values
from Appendix B to calculate this value. SOLUTION: DHrxn = [(2
mol)(DHf of NH3)] - [(1 mol)(DHf of N2) + (3 mol)(DHf of H2)] = [(2
mol)(-45.9 kJ/mol)] - [(1 mol)(0 kJ/mol) + (3 mol)(0 kJ/mol)] =
91.8 kJ Sample Problem 20.3 = - -91.8 kJx 1000 J 1 kJ 298 K DSsurr
= - DHsys T = 308 J/K DSuniv = DSsys + DSsurr = -797 J/K J/K = 111
J/K Since DSuniv > 0, the reaction occurs spontaneously at 298
K. Although the entropy of the system decreases, this is outweighed
by the increase in the entropy of the surroundings. Figure 20.12 A
whole-body calorimeter. In this room-sized apparatus, a person
exercises while respiratory gases, energy input and output, and
other physiological variables are monitored. Biological systems
also obey the laws of thermodynamics. For all processes, however
complex, the entropy of the university increases. DS and the
Equilibrium State
For any process approaching equilibrium, DSuniv > 0. At
equilibrium, there is no further net change, and DSsys is balanced
by DSsurr. DSuniv = DSsys + DSsurr = 0, so DSsys = - DSsurr When a
system reaches equilibrium, neither the forward nor the reverse
reaction is spontaneous, so there is no net reaction in either
direction. Components of DSuniv for spontaneous reactions.
Figure 20.13AB Components of DSuniv for spontaneous reactions.
exothermic For an exothermic reaction in which DSsys > 0, the
size of DSsurr is not important since DSsurr > 0 for all
exothermic reactions. The reaction will always be spontaneous.
exothermic For an exothermic reaction in which DSsys < 0, DSsurr
must be larger than DSsys for the reaction to be spontaneous.
Components of DSuniv for spontaneous reactions.
Figure 20.13C Components of DSuniv for spontaneous reactions.
endothermic For an endothermic reaction in which DSsys > 0,
DSsurr must be smaller than DSsys for the reaction to be
spontaneous. DSsurr is always < 0 for endothermic reactions.
Gibbs Free Energy The Gibbs free energy (G) combines the enthalpy
and entropy of a system; G = H TS. The free energy change (DG) is a
measure of the spontaneity of a process and of the useful energy
available from it. DGsys = DHsys - T DSsys DG < 0 for a
spontaneous process DG > 0 for a nonspontaneous process DG = 0
for a process at equilibrium Calculating DG DGrxn can be calculated
using the Gibbs equation:
DGsys = DHsys - T DSsys DGrxncan be calculated using the Gibbs
equation: DGrxncan also be calculated using values for the standard
free energy of formation of the components. DGrxn = SmDGproducts -
SnDGreactants Calculating DGrxn from Enthalpy and Entropy
Values
Sample Problem 20.4 Calculating DGrxn from Enthalpy and Entropy
Values PROBLEM: Potassium chlorate, a common oxidizing agent in
fireworks and matchheads, undergoes a solid-state
disproportionation reaction when heated. 4KClO3(s) KClO4(s) +
KCl(s) +7 -1 +5 PLAN: To solve for DG, we need values from Appendix
B. We use DHf to calculate DHrxn, use S values to calculate DSrxn
and then apply the Gibbs equation. SOLUTION: DHrxn =
SmDHf(products) - SnDHf(reactants) = [(3 mol KClO4)(DHf of KClO4) +
(1 mol KCl)(DHf of KCl)] [(4 mol KClO3)(DHf of KClO3)] = [(3 mol)(
kJ/mol) + (1 mol)( kJ/mol) [(4 mol)( kJ/mol)] = 144 kJ Sample
Problem 20.4 DSrxn = SmS(products) - SS(reactants) = [(3 mol of
KClO4)(S of KClO4) + (1 mol KCl)(S of KCl)] [(4 mol KClO3)(S of
KClO3)] = [(3 mol)(151.0 J/molK) + (1 mol)(82.6 J/molK) [(4 mol)(
kJ/mol)] = J/K DGsys = DHsys - T DSsys = 144 kJ (298 K)(-36.8 J/K)
1000 J 1 kJ = -133 kJ Calculating DGrxn from DGf Values
Sample Problem 20.5 Calculating DGrxn from DGf Values PROBLEM: Use
DGf values to calculate DGrxn for the reaction in Sample Problem
20.4: 4KClO3(s) KClO4(s) + KCl(s) PLAN: We apply Equation 20.8 and
use the values from Appendix B to calculate DGrxn. SOLUTION: DGrxn
= SmDGproducts - SnDGreactants = [(3 mol KClO4)(DGf of KClO4) + (1
mol KCl)(DGf of KCl)] [(4 mol KClO3)(DGf of KClO3)] = [(3 mol)(
kJ/mol) + (1 mol)( kJ/mol)] [(4 mol)( kJ/mol)] = -134 kJ DG and
Useful Work DG is the maximum useful work done by a system during a
spontaneous process at constant T and P. In practice, the maximum
work is never done. Free energy not used for work is lost to the
surroundings as heat. DG is the minimum work that must be done to a
system to make a nonspontaneous process occur at constant T and P.
A reaction at equilibrium (DGsys = 0) can no longer do any work.
Figure 20.14 An expanding gas lifting a weight. Effect of
Temperature on Reaction Spontaneity
DGsys = DHsys - T DSsys Reaction is spontaneous at all temperatures
If DH < 0 and DS > 0 DG < 0 for all T Reaction is
nonspontaneous at all temperatures If DH > 0 and DS < 0 DG
> 0 for all T Effect of Temperature on Reaction
Spontaneity
Reaction becomes spontaneous as T increases If DH > 0 and DS
> 0 DG becomes more negative as Tincreases. Reaction becomes
spontaneous as T decreases If DH < 0 and DS < 0 DG becomes
more negative as Tdecreases. Table 20.1Reaction Spontaneity and the
Signs of DH, DS, and DG
-TDS DG Description + Spontaneous at all T Nonspontaneous at all T
+ or Spontaneous at higher T; nonspontaneous at lower T Spontaneous
at lower T; nonspontaneous at higher T Sample Problem 20.6 Using
Molecular Scenes to Determine the Signs of DH, DS, and DG PROBLEM:
The following scenes represent a familiar phase change for water
(blue spheres). (a)What are the signs of DH and DS for this
process?Explain. (b)Is the process spontaneous at all T, no T, low
T, or high T?Explain. PLAN: (a) From the scenes, we determine any
change in the amount of gas, which indicates the sign of DS, and
any change in the freedom of motion of the particles, which
indicates whether heat is absorbed or released. (b)To determine
reaction spontaneity we need to consider the sign of DG at
different temperatures. Sample Problem 20.6 SOLUTION:
(a)The scene represents the condensation of water vapor, so the
amount of gas decreases dramatically, and the separated molecules
give up energy as they come closer together. DS < 0 and DH >
0 (b)Since DS is negative and DH is positive, the TDS term is
positive. In order for DG to be < 0, the temperature must be
low. The process is spontaneous at low temperatures. Sample Problem
20.7 Determining the Effect of Temperature on G PROBLEM: A key step
in the production of sulfuric acid is the oxidation of SO2(g) to
SO3(g): 2SO2(g) + O2(g) 2SO3(g) At 298 K, DG = kJ; DH = kJ;and DS =
J/K (a)Use the data to decide if this reaction is spontaneous at
25C, and predict how DG will change with increasing T. (b)Assuming
DH and DSare constant with increasing T, is the reaction
spontaneous at 900. C? PLAN: We note the sign of DG to see if the
reaction is spontaneous and the signs of DH and DS to see the
effect of T. We can then calculate whether or not the reaction is
spontaneous at the higher temperature. Sample Problem 20.7
SOLUTION: (a) DG < 0 at 209 K (= 25C), so the reaction is
spontaneous. With DS < 0, the term -TDS > 0 and this term
will become more positive at higher T. DG will become less
negative, and the reaction less spontaneous, with increasing T.
(b)DG = DH - TDS Convert T to K: = 1173 K Convert S to kJ/K: J/K =
kJ/K DG = kJ [1173 K)( kJ/K) = 22.0 kJ DG > 0, so the reaction
is nonspontaneous at 900.C. The sign of DG switches at
Figure 20.15 The effect of temperature on reaction spontaneity. DH
S T = The sign of DG switches at Sample Problem 20.8 Finding the
Temperature at Which a Reaction Becomes Spontaneous PROBLEM: At 25C
(298 K), the reduction of copper(I) oxide is nonspontaneous DG =
8.9 kJ). Calculate the temperature at which the reaction becomes
spontaneous. PLAN: We need to calculate the temperature at which DG
crosses over from a positive to a negative value. We set DG equal
to zero, and solve for T, using the values for DH and DS from the
text. SOLUTION: DH DS T = = 58.1 kJ 0.165 kJ/K = 352 K At any
temperature above 352 K (= 79C), the reaction becomes spontaneous.
Chemical Connections Figure B20.1 The coupling of a nonspontaneous
reaction to the hydrolysis of ATP. A spontaneous reaction can be
coupled to a nonspontaneous reaction so that the spontaneous
process provides the free energy required to drive the
nonspontaneous process. The coupled processes must be physically
connected. Chemical Connections Figure B20.2 The cycling of
metabolic free energy. Chemical Connections Figure B20.3 ATP is a
high-energy molecule. When ATP is hydrolyzed to ADP, the decrease
in charge repulsion (A) and the increase in resonance stabilization
(B) causes a large amount of energy to be released. DG,
Equilibrium, and Reaction Direction
A reaction proceeds spontaneously to the right if Q < K; < 1
so ln < 0 and DG < 0 Q K A reaction proceeds spontaneously to
the left if Q > K; > 1 so ln > 0and DG > 0 Q K A
reaction is at equilibrium if Q = K; = 1 so ln = 0and DG = 0 Q K
DG, Q, and K Q DG = RT ln = RT lnQ RT lnK K
If Q and K are very different, DG has a very large value (positive
or negative). The reaction releases or absorbs a large amount of
free energy. If Q and K are nearly the same, DG has a very small
value (positive or negative). The reaction releases or absorbs very
little free energy. G and the Equlibrium Constant
For standard state conditions, Q = 1 and DG = -RT lnK A small
change in DG causes a large change in K, due to their logarithmic
relationship. As DG becomes more positive, K becomes smaller. As DG
becomes more negative, K becomes larger. DG = DG + RT lnQ To
calculate DG for any conditions: { { { Table 20.2 The Relationship
Between DG and K at 298 K DG (kJ)
Significance 200 9x10-36 Essentially no forward reaction; reverse
reaction goes to completion 100 3x10-18 50 2x10-9 10 2x10-2 1
7x10-1 Forward and reverse reactions proceed to same extent -1 1.5
-10 5x101 -50 6x108 -100 3x1017 Forward reaction goes to
completion; essentially no reverse reaction -200 1x1035 { FORWARD
REACTION REVERSE REACTION { { A2(g) + B2(g) 2AB(g) DGo = -3.4
kJ/mol
Sample Problem 20.9 Using Molecular Scenes to Find DGfor a Reaction
at Nonstandard Conditions PROBLEM: These molecular scenes represent
three mixtures in which A2 (black) and B2 (green) are forming
AB.Each molecule represents 0.10 atm. The equation is A2(g)+B2(g)
AB(g) DGo = -3.4 kJ/mol (a)If mixture 1 is at equilibrium,
calculate K. (b)Which mixture has the most negative DG, and which
has the most positive? (c)Is the reaction spontaneous at the
standard state, that is P= P= PAB = 1.0 atm? A2 B2 (c) Since 1.0
atm is the standard state for gases, DG = DG.
Sample Problem 20.9 PLAN: (a)Mixture 1 is at equilibrium, so we
first write the expression for Q and then find the partial pressure
of each substance from the number of molecules and calculate K.
(b)To find DG, we apply equation We can calculate the value of T
using K from part (a), and substitute the partial pressure of each
substance to get Q. (c)Since 1.0 atm is the standard state for
gases, DG = DG. SOLUTION: (a) Q = PAB2 P x P A2 B2 A2(g)+B2(g)
AB(g) K = (0.40)2 (0.20)(0.20) = 4.0 Mixture 1 is at equilibrium,
so G = 0; DG = DG + RT lnQ
Sample Problem 20.9 (b) DG = -RT lnK T = -3.4 kJ mol 1000 J 1 kJ
8.314 J molK ln 4.0 - = 295 K = - -3.4 kJ mol T ln 4.0 8.314 J molK
Mixture 1 is at equilibrium, so G = 0; DG = DG + RT lnQ = J/mol +
(8.314 J/molK)(295 K)(ln 4.0) = J J = 0.0 J Mixture 2: (0.20)2
(0.30)(0.30) Q = = 0.44 DG = DG + RT lnQ = J/mol + (8.314
J/molK)(295 K)(ln 0.44) = J 2010 J = -5.4x10-3 J Sample Problem
20.9 Mixture 3: (0.60)2 (0.10)(0.10) Q = = 36 DG = DG + RT lnQ =
J/mol + (8.314 J/molK)(295 K)(ln 36) = J J = +5.4x10-3 J Mixture 2
has the most negative DG, and mixture 3 has the most positive DG.
(c)Under standard conditions, DG = DG = -3.4 kJ/mol. Yes, the
reaction is spontaneous when the components are in their standard
states. Sample Problem 20.10 Calculating DG at Nonstandard
Conditions PROBLEM: The oxidation of SO2(g) is too slow at 298 K to
be useful in the manufacture of sulfuric acid, so the reaction is
run at high T. 2SO2(g) + O2(g) 2SO3(g) (a)Calculate K at 298 K and
at 973 K, (DG298 = kJ/mol of reaction as written; using DH and
DSvalues at 973 K, DG973 = kJ/mol for reaction as written.) (b)Two
containers are filled with atm of SO2, atm of O2, and atm of SO3;
one is kept at 25C and the other at 700.C. In which direction, if
any, will the reaction proceed to reach equilibrium at each
temperature? (c)Calculate DG for the system in part (b) at each
temperature. Sample Problem 20.10 PLAN: (a)We know DG, T, and R, so
we can calculate the values of K at each temperature. (b)To
determine if a net reaction will occur, we find Q from the given
partial pressures and compare Q to K from part (a). of each
substance to get Q. (c)These are not standard-state pressures, so
we find DG at each temperature using the equation DG = DG + RT lnQ.
SOLUTION: K = e -(DG/RT) (a) DG = -RT lnK so -141.6x103 J/mol 8.314
J/molK x 298 K At 298 K, -(DG)/RT = = 57.2 K at 298 K = e57.2 =
7x1024 (b) Calculating the value of Q
Sample Problem 20.10 -12.12x103 J/mol 8.314 J/molK x 973 K At 973
K, -(DG)/RT = = 1.50 K at 973 K = e1.50 = 4.5 (b)Calculating the
value of Q P2 P2 x P SO3 SO2 O2 Q = = (0.100)2 (0.500)2(0.0100) =
4.00 Since Q < K at both temperatures, the reaction will proceed
toward the products (to the right) in both cases until Q equals K.
At 298 K, the system is far from equilibrium and will proceed far
to the right. At 973 K the system is closer to equilibrium and will
proceed only slightly toward the right. Sample Problem 20.10 (c)
DG298 = DG + RT ln Q = kJ/mol + (8.314x10-3 kJ/molK x 298 K x ln
4.00) = kJ/mol DG973 = DG + RT ln Q = kJ/mol + (8.314x10-3 kJ/molK
x 973 K x ln 4.00) = -0.9 kJ/mol Figure 20.16 Free energy and the
extent of reaction. Each reaction proceeds spontaneously (green
curved arrows) from reactants or products to the equilibrium
mixture, at which point DG = 0. After that, the reaction is
nonspontaneous in either direction (red curved arrows). Free energy
reaches a minimum at equilibrium.