1 Keys To Studying Chemistry: Definitions, Units, And Problem Solving 2 The Components Of Matter 3 Stoichiometry Of Formulas And Equations 4 Three Major Classes Of Chemical Reactions 5 Gases And The Kinetic-molecular Theory 6 Thermochemistry: Energy Flow And Chemical Change 7 Quantum Theory And Atomic Structure 8 Electron Configuration And Chemical Periodicity 9 Models Of Chemical Bonding 10 The Shapes Of Molecules 11 Theories Of Covalent Bonding 12 Intermolecular Forces: Liquids, Solids, And Phase Changes 13 The Properties Of Mixtures: Solutions And Colloids 14 Periodic Patterns In The Main-group Elements 15 Organic Compounds And The Atomic Properties Of Carbon 16 Kinetics: Rates And Mechanisms Of Chemical Reactions 17 Equilibrium: The Extent Of A Chemical Reactions 18 Acid-base Equilibria 19 Ionic Equilibria In Aqueous Systems 20 Thermodynamics: Entropy, Free Energy, And Reaction Direction 21 Electrochemistry: Chemical Change And Electrical Work 22 The Elements In Nature And Industry 23 Transition Elements And Their Coordination Compounds 24 Nuclear Reactions And Their Applications expand_more
17.1 The Equilibrium State And The Equilibrium Constant 17.2 The Reaction Quotient And The Equilibrium Constant 17.3 Expressing Equilibria With Pressure Terms: Relation Between Kc And Kp 17.4 Comparing Q And K To Determine Reaction Direction 17.5 How To Solve Equilibrium Problems 17.6 Reaction Conditions And Equilibrium: Le Chatelier's Principle Chapter Questions expand_more
Problem 17.1P Problem 17.2P: When a chemical company employs a new reaction to manufacture a product, the chemists consider its... Problem 17.3P: If there is no change in concentrations, why is the equilibrium state considered dynamic?
Problem 17.4P Problem 17.5P Problem 17.6P Problem 17.7P Problem 17.8P Problem 17.9P Problem 17.10P: Does Q for the formation of 1 mol of NO from its elements differ from Q for the decomposition of 1... Problem 17.11P: Does Q for the formation of 1 mol of NH3 from H2 and N2 differ from Q for the formation of NH3 from... Problem 17.12P: Balance each reaction and write its reaction quotient, Qc:
NO(g) + O2(g) ⇌ N2O3(g)
SF6(g) + SO3(g) ⇌... Problem 17.13P Problem 17.14P Problem 17.15P Problem 17.16P: At a particular temperature, Kc = 1.6×10−2 for
Calculate Kc for each of the following... Problem 17.17P Problem 17.18P: Balance each of the following examples of heterogeneous equilibria and write each reaction quotient,... Problem 17.19P: Balance each of the following examples of heterogeneous equilibria and write each reaction quotient,... Problem 17.20P: Balance each of the following examples of heterogeneous equilibria and write each reaction quotient,... Problem 17.21P: Balance each of the following examples of heterogeneous equilibria and write each reaction quotient,... Problem 17.22P Problem 17.23P Problem 17.24P Problem 17.25P Problem 17.26P: When are Kc and Kp equal, and when are they not?
Problem 17.27P: A certain reaction at equilibrium has more moles of gaseous products than of gaseous reactants.
Is... Problem 17.28P Problem 17.29P: Determine Δngas for each of the following reactions:
MgCO3(s) ⇌ MgO(s) + CO2(g)
2H2(g) + O2(g) ⇌... Problem 17.30P Problem 17.31P Problem 17.32P Problem 17.33P Problem 17.34P Problem 17.35P: The following molecular scenes depict the aqueous reaction 2D ⇌ E, with D red and E blue. Each... Problem 17.36P: At 425°C, Kp = 4.18 × 10−9 for the reaction
2HBr(g) ⇌ H2(g) + Br2(g)
In one experiment, 0.20 atm of... Problem 17.37P: At 100°C, Kp = 60.6 for the reaction
2NOBr(g) ⇌ 2NO(g) + Br2(g)
In a given experiment, 0.10 atm of... Problem 17.38P: The water-gas shift reaction plays a central role in the chemical methods for obtaining cleaner... Problem 17.39P: In the 1980s, CFC-11 was one of the most heavily produced chlorofluorocarbons. The last step in its... Problem 17.40P: For a problem involving the catalyzed reaction of methane and steam, the following reaction table... Problem 17.41P: What is the basis of the approximation that avoids the need to use the quadratic formula to find an... Problem 17.42P Problem 17.43P: Gaseous ammonia was introduced into a sealed container and heated to a certain temperature:
2NH3(g)... Problem 17.44P Problem 17.45P Problem 17.46P Problem 17.47P Problem 17.48P Problem 17.49P Problem 17.50P Problem 17.51P: Nitrogen dioxide decomposes according to the reaction
2NO2(g) ⇌ 2NO(g) + O2(g)
where Kp = 4.48 ×... Problem 17.52P: Hydrogen iodide decomposes according to the reaction
2HI(g) ⇌ H2(g) + I2(g)
A sealed 1.50-L... Problem 17.53P: Compound A decomposes according to the equation
A(g) ⇌ 2B(g) + C(g)
A sealed 1.00-L container... Problem 17.54P: In an analysis of interhalogen reactivity, 0.500 mol of ICl was placed in a 5.00-L flask, where it... Problem 17.55P: A toxicologist studying mustard gas, S(CH2CH2Cl)2, a blistering agent, prepares a mixture of 0.675 M... Problem 17.56P Problem 17.57P: A key step in the extraction of iron from its ore is FeO(s) + CO(g) ⇌ Fe(s) + CO2(g) Kp = 0.403 at... Problem 17.58P: What does “disturbance” mean in Le Châtelier’s principle?
Problem 17.59P Problem 17.60P Problem 17.61P Problem 17.62P: Le Châtelier’s principle is related ultimately to the rates of the forward and reverse steps in a... Problem 17.63P: An equilibrium mixture of two solids and a gas, in the reaction , is depicted at right (X is green... Problem 17.64P: Consider this equilibrium system:
CO(g) + Fe3O4(s) ⇌ CO2(g) + 3FeO(s)
How does the equilibrium... Problem 17.65P: Sodium bicarbonate undergoes thermal decomposition according to the reaction
2NaHCO3(s) ⇌ Na2CO3(s)... Problem 17.66P Problem 17.67P Problem 17.68P: Predict the effect of decreasing the container volume on the amounts of each reactant and product in... Problem 17.69P Problem 17.70P Problem 17.71P Problem 17.72P Problem 17.73P Problem 17.74P Problem 17.75P: The formation of methanol is important to the processing of new fuels. At 298 K, Kp = 2.25×104 for... Problem 17.76P Problem 17.77P: The oxidation of SO2 is the key step in H2SO4 production:
SO2(g) + O2(g) ⇌ SO3(g)
What qualitative... Problem 17.78P: A mixture of 3.00 volumes of H2 and 1.00 volume of N2 reacts at 344°C to form ammonia. The... Problem 17.79P: You are a member of a research team of chemists discussing plans for a plant to produce... Problem 17.80P: For the following equilibrium system, which of the changes will form more CaCO3?
CO2(g) + Ca(OH)2(s)... Problem 17.81P Problem 17.82P Problem 17.83P Problem 17.84P Problem 17.85P Problem 17.86P Problem 17.87P Problem 17.88P Problem 17.89P: When 0.100 mol of CaCO3(s) and 0.100 mol of CaO(s) are placed in an evacuated sealed 10.0-L... Problem 17.90P Problem 17.91P Problem 17.92P Problem 17.93P: Highly toxic disulfur decafluoride decomposes by a free-radical process: S2F10(g) ⇌ SF4(g) + SF6(g).... Problem 17.94P: A study of the water-gas shift reaction (see Problem 17.38) was made in which equilibrium was... Problem 17.95P Problem 17.96P Problem 17.97P Problem 17.98P Problem 17.99P Problem 17.100P Problem 17.101P: The molecular scenes below depict the reaction Y ⇌ 2Z at four different times, out of sequence, as... Problem 17.102P: For the equilibrium
H2S(g) ⇌ 2H2(g) + S2(g) Kc = 9.0 × 10−8 at 700°C
the initial concentrations of... Problem 17.103P Problem 17.104P Problem 17.105P: The kinetics and equilibrium of the decomposition of hydrogen iodide have been studied... Problem 17.106P: Isopentyl alcohol reacts with pure acetic acid to form isopentyl acetate, the essence of banana... Problem 17.107P: Isomers Q (blue) and R (yellow) interconvert. They are depicted in an equilibrium mixture in scene... Problem 17.108P: Glauber’s salt, Na2SO4·10H2O, was used by J. R. Glauber in the 17th century as a medicinal agent. At... Problem 17.109P Problem 17.110P: Synthetic diamonds are made under conditions of high temperature (2000 K) and high pressure (1010... format_list_bulleted