Deck 15: Chemical Equilibrium: How Much Product Does a Reaction Really Make

A) 0.5
B) 2.0
C) 20
D) 0.050
E) 5.0

A) $\frac { \left[ \mathrm { CO } _ { 2 } \right] } { [ \mathrm { CO } ] \left[ \mathrm { O } _ { 2 } \right] }$
B) $\frac { \left[ \mathrm { CO } _ { 3 } \right] \left[ \mathrm { O } _ { 2 } \right] } { \left[ \mathrm { CO } _ { 2 } \right] }$
C) $\frac { [ \mathrm { CO } ] \left[ \frac { 1 } { 2 } \mathrm { O } _ { 2 } \right] } { \left[ \mathrm { CO } _ { 2 } \right] }$
D) $\frac { \left[ \mathrm { CO } ^ { 2 } \left[ \mathrm { O } _ { 2 } \right] \right. } { \left[ \mathrm { CO } _ { 2 } \right] ^ { 2 } }$
E) None of these ratios correctly describes the equilibrium concentrations.

A) The reaction will be unable to achieve equilibrium.
B) k_f and k_r will become equal as equilibrium is approached owing to concentration changes.
C) k_f and k_r will become equal as equilibrium is approached owing to temperature changes.
D) k_f and k_r will remain unequal but the rates will become equal owing to concentration changes.
E) k_f and k_r will remain unequal but the rates will become equal owing to temperature changes.

A) $\frac { \left[ \mathrm { CO } _ { 2 } \right] } { [ \mathrm { CO } ] \left[ \mathrm { O } _ { 2 } \right] }$
B) $\frac { \left[ \mathrm { CO } _ { 3 } \right] \left[ \mathrm { O } _ { 2 } \right] } { \left[ \mathrm { CO } _ { 2 } \right] }$
C) $\frac { [ \mathrm { CO } ] \left[ \frac { 1 } { 2 } \mathrm { O } _ { 2 } \right] } { \left[ \mathrm { CO } _ { 2 } \right] }$
D) $\frac { [ \mathrm { CO } ] \left[ \mathrm { O } _ { 2 } \right] ^ { 1 / 2 } } { \left[ \mathrm { CO } _ { 2 } \right] }$
E) $\frac { \frac { 1 } { 2 } [ \mathrm { CO } ] \left[ \mathrm { O } _ { 2 } \right] } { \left[ \mathrm { CO } _ { 2 } \right] }$

A) I only
B) II and III
C) I, II, and III
D) I and II
E) I and III

A) $K = \left[ \mathrm { Zn } ^ { 2 + } \right] + 2 \left[ \mathrm { NH } _ { 3 } \right] + \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right]$
B) $K = \frac { \left[ \mathrm { Zn } ^ { 2 + } \right] + 2 \left[ \mathrm { NH } _ { 3 } \right] } { \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] }$
C) $K = \frac { \left[ \mathrm { Zn } ^ { 2 + } \right] \left[ \mathrm { NH } _ { 3 } \right] ^ { 2 } } { \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] }$
D) $K = \frac { \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] } { \left[ \mathrm { Zn } ^ { 2 + } \right] \left[ \mathrm { NH } _ { 3 } \right] ^ { 2 } }$
E) $K = \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] - \left[ \mathrm { Zn } ^ { 2 + } \right] - 2 \left[ \mathrm { NH } _ { 3 } \right]$

A) 3.5 * 10⁵
B) 3.4 * 10²
C) 4.2 *10¹³
D) 2.9 *10^-3
E) 6.0 * 10^-5

A) They will not change because there are no more reactants.
B) They will not change because the limiting reagent is gone.
C) They will not change because this is a constant for each reaction.
D) They will not change because the forward and reverse rates are equal.
E) They will change continually because of reversibility.

A) $\left. K = [ \text { fool (money) } ) _ { 10 } \right] [ \text { fool } ] [ \text { money } ]$
B) $K = \frac { [ \text { fool } ] [ \text { money } ] ^ { 10 } } { \left[ \text { fool } ( \text { money } ) _ { 10 } \right] }$
C) $K = \left[ \text { fool } ( \text { money } ) _ { 10 } \right] [ \text { fool } ] [ \text { money } ] ^ { 10 }$
D) $K = \frac { \left[ \text { fool } ( \text { money } ) _ { 10 } \right] ^ { 10 } } { [ \text { fool] [money] } }$
E) $K = [ \text { fool } ] + 10 [ \text { money } ] - \left[ \text { fool } ( \text { money } ) _ { 10 } \right]$

A) Can't tell, need more information.
B) [A] = [B]
C) [A] = 2 *[B]
D) [A] = $\frac { 1 } { 2 } \times$
[B]
E) [A] = 4 *[B]

A) [A] = K
B) [A] = [B] = [C]
C) [B] = [C] = K
D) [A] = 1/K
E) [C]/[B] = K

A) reactants only.
B) products only.
C) equal quantities of reactants and products.
D) any quantities of reactants and products.
E) All of the above.

A) the concentrations of reactants and products
B) the rate constants for the forward and reverse reactions
C) the time that a particular atom or molecule spends as a reactant and product
D) the rate of the forward and reverse reaction
E) All of the above are equal.

A) All chemical reactions are reversible since products can be converted back into the reactants.
B) If a reaction is characterized as lying far to the left, then the concentration of products is small when equilibrium is reached.
C) At equilibrium, the rates of the forward reaction and reverse reaction are equal.
D) At equilibrium, the rates of the forward and reverse reactions are equal because both have stopped.
E) Chemical equilibrium is said to be "a dynamic process."

A) only the forward reaction stops
B) only the reverse reaction stops
C) both the forward and reverse reactions stop
D) the rate constants for the forward and reverse reactions are equal
E) the rates of the forward and reverse reactions are equal

A) 20.0
B) 2.0
C) 0.20
D) 0.020
E) 200

A) the law of conservation of matter.
B) the law of conservation of energy.
C) kinetics of reversible reactions.
D) limiting reactant stoichiometry.
E) the third law of thermodynamics.

A) Can't tell, need more information.
B) 0.25
C) 4
D) 16
E) 0.5

A) I only
B) II only
C) III only
D) I and II
E) I and III

A) I and III
B) I and IV
C) II and III
D) II and IV
E) None are true, as the concentrations of reactants and products are comparable.

A) each concentration must be multiplied by the factor RT.
B) each pressure must be multiplied by the factor RT.
C) K_c must be multiplied by the factor RT.
D) K_P must be multiplied by the factor RT.
E) nothing must be done because their values are equal.

A) 0.22
B) 9.9
C) 4.3 *10⁵
D) 2.3* 10⁸
E) 9.5 * 10³

A) there is no change in the moles of gas in the reaction
B) there is no change in the temperature during the reaction
C) if the coefficients of the reactants and products are the same
D) if the pressure remains constant
E) if either K_c or K_p = 1

A) Values for each can be determined using units of moles/liter or atmospheres.
B) K is the reciprocal of Q: K = 1/Q.
C) K always is larger than Q.
D) Q always is larger than K.
E) Q can never equal K.

A) 5.3 *10^-4
B) 3.5 *10^-6
C) 6.3*10^-5
D) 1.6 *10⁴
E) 3.0 *10⁴

A) 0.10
B) 0.20
C) 0.010
D) 20
E) 10

A) 10
B) 20
C) 40
D) 100
E) 400

A) 0.10
B) 10
C) 1
D) 100
E) -10

A) I and III
B) I and IV
C) II and III
D) II and IV
E) None are true, as the concentrations of reactants and products are essentially the same.

A) a value of K << 1.
B) a value of K >> 1.
C) a value of Q >> 1.
D) a value of Q << 1.
E) K = Q.

A) the same, 2.2 *10⁸
B) -2.2 * 10⁸
C) 2.2 *10^-8
D) 4.5 * 10^-9
E) 4.5 * 10⁹

A) 10.0
B) 1.36
C) 13.6
D) 2.46
E) 24.6

A) K_aK_b
B) K_a + 4K_b
C) K_a + K_b⁴
D) K_aK_b⁴
E) K_aK_b^1/4

A) 0.32
B) 10
C) 3.2
D) 3.1
E) 32

A) $Q = \left[ \mathrm { Zn } ^ { 2 + } \right] + 2 \left[ \mathrm { NH } _ { 3 } \right] + \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right]$
B) $Q = \frac { \left[ \mathrm { Zn } ^ { 2 + } \right] + 2 \left[ \mathrm { NH } _ { 3 } \right] } { \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] }$
C) $Q = \frac { \left[ \mathrm { Zn } ^ { 2 + } \right] \left[ \mathrm { NH } _ { 3 } \right] ^ { 2 } } { \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] }$
D) $Q = \frac { \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] } { \left[ \mathrm { Zn } ^ { 2 + } \right] \left[ \mathrm { NH } _ { 3 } \right] ^ { 2 } }$
E) $Q = \left[ \mathrm { Zn } \left( \mathrm { NH } _ { 3 } \right) ^ { 2 + } \right] - \left[ \mathrm { Zn } ^ { 2 + } \right] - 2 \left[ \mathrm { NH } _ { 3 } \right]$

A) The values vary according to the way the measurement is made. Ken must have measured product concentrations, while Barbie measured reactant concentrations.
B) The values vary according to the starting conditions of the reaction prior to equilibrium. Ken must have started with all reactants, while Barbie must have started with all products.
C) The values vary according to the stoichiometric coefficients that are used. The balancing coefficients that Ken used must have been twice those that Barbie used.
D) The values vary according to direction of the reaction. Ken must have used the reverse reaction.
E) The instructor must have made a mistake, because the equilibrium constant for a reaction must always be the same.

A) K_p > K_c.
B) K_p < K_c.
C) K_p = K_c.
D) K_p + K_c = (RT) ^{$\Delta$ n}.
E) K_pK_c = (RT) ^{$\Delta$ n}

A) 4.70
B) 290
C) 206
D) 19.5
E) 4.86

A) K_c and K_p are equal when all stoichiometric coefficients in the balanced reaction equation equal one.
B) K_c and K_p have the same values but different units.
C) K_c and K_p are equal when the sum of the stoichiometric coefficients for the products equals the sum of the stoichiometric coefficients for the reactants.
D) K_c and K_p can never be equal.
E) K_c and K_p are equal when the conditions are standard (P = 1 atm, T = 298 K).

A) I only
B) II only
C) III only
D) I and II only
E) I and III only

A) 0.023
B) 1.5 *10^-4
C) 2.7 *10^-3
D) 370
E) 4.4 * 10⁴

A) Q increases and the equilibrium shifts to produce more products.
B) Q increases and the equilibrium shifts to produce more reactants.
C) Q decreases and the equilibrium shifts to produce more products.
D) Q decreases and the equilibrium shifts to produce more reactants.
E) Q is unchanged by the removal of products.

A) have the assigned value of one.
B) have the assigned value of zero.
C) have constant values, c_S and c_l.
D) are determined from the density and molar mass.
E) are treated as any other solute.

A) only that [B] = [C]
B) [A] = [B] = [C]
C) [B] = [C] = K
D) [A] = K
E) The reaction must run in the forward direction.

A) the amount of CO₂(g) would double.
B) the amount of CO₂(g) would increase but not double.
C) the partial pressure of CO₂(g) would increase.
D) the amount of CO₂(g) would not change.
E) the equilibrium amount of CO₂(s) would be less.

A) No, these two stresses will always cancel each other out.
B) No, these two stresses will cancel each other out unless the initial concentrations of B and C are also the same.
C) Yes, the same amount of A is also required for the stresses to cancel each other out.
D) Yes, unless the initial concentrations of B and C are also the same.
E) More than two of the above statements are correct.

A) I only
B) II only
C) III only
D) I and II
E) II and III

A) $\frac { \left[ \mathrm { CaCO } _ { 3 } \right] } { [ \mathrm { CaO } ] \left[ \mathrm { CO } _ { 2 } \right] }$
B) $\frac { 1 } { \mathrm { P } _ { \mathrm { Co } _ { 2 } } }$
C) $\frac { [ \mathrm { CaO } ] \left[ \mathrm { CO } _ { 2 } \right] } { \left[ \mathrm { CaCO } _ { 3 } \right] }$
D) [CaO][CO₂]
E) $\mathrm { P } _ { \mathrm { co } _ { 2 } }$

A) the reaction is at equilibrium.
B) the reaction will continue to make more products.
C) the reaction will consume products and make reactants.
D) the reaction will release heat to achieve equilibrium.
E) the value of K will increase until it is equal to Q.

A) the reaction is at equilibrium.
B) the reaction will continue to make more products.
C) the reaction will consume products and make reactants.
D) the reaction will release heat to achieve equilibrium.
E) the value of K will decrease until it is equal to Q.

A) I only
B) II only
C) I and III
D) I, III, and IV
E) I and IV

A) The ratio of NO₂ to N₂O₄ increases solely because of the increase in volume.
B) The ratio of NO₂ to N₂O₄ increases solely because of the addition of argon.
C) The ratio of NO₂ to N₂O₄ decreases solely because of the increase in volume.
D) The ratio of NO₂ to N₂O₄ decreases solely because of the addition of argon.
E) The ratio of NO₂ to N₂O₄ remains the same, because the effects of the two processes cancel each other out.

A) K_c = [SO₂]
B) $K _ { c } = \frac { 1 } { \left[ \mathrm { SO } _ { 2 } \right] }$
C) K_c = [CaO] + [SO₂]
D) $K _ { \mathrm { c } } = \frac { \left[ \mathrm { CaSO } _ { 3 } \right] } { \left[ \mathrm { SO } _ { 2 } \right] [ \mathrm { CaO } ] }$
E) K_c = [CaSO₃] - [CaO] - [SO₂]

A) Q increases and the equilibrium shifts to produce more products.
B) Q increases and the equilibrium shifts to produce more reactants.
C) Q decreases and the equilibrium shifts to produce more products.
D) Q decreases and the equilibrium shifts to produce more reactants.
E) Q is unchanged by the addition of reactants.

A) an increase in K and a shift in equilibrium to produce more products.
B) an increase in K and a shift in equilibrium to produce more reactants.
C) a decrease in K and a shift in equilibrium to produce more products.
D) a decrease in K and a shift in equilibrium to produce more reactants.
E) no change in K and a shift in equilibrium to produce more products.

A) by heating calcium sulfite at 900 $\degree$ C.
B) as a by-product of burning coal.
C) from the reaction between calcium oxide and sulfur dioxide.
D) by heating calcium carbonate at 900 $\degree$ C.
E) from sweet soil.

A) limestone (CaCO₃).
B) lime (CaO).
C) calcium metal (Ca).
D) calcium hydride (CaH₂).
E) calcium hydroxide [Ca(OH)₂].

A) 1.00
B) 2.96* 10^-4
C) 6.67*10^-2
D) 4.44 *10^-3
E) 3.33*10^-2

A) adding reactants to a gas or solution reaction
B) removing products from a gas or solution reaction
C) decreasing the temperature
D) increasing pressure by adding an inert gas to a reaction in the gas phase
E) All of the above are perturbations to chemical equilibrium.

A) more than 0.033 atm
B) less than 0.033 atm
C) 0.033 atm exactly
D) there is no way to tell

A) 0.500 atm
B) 0.680 atm
C) 0.859 atm
D) 0.029 atm
E) 0.987 atm

A) 0.85 M
B) 1.69 M
C) 2.85 M
D) 3.37 M
E) 4.00 M

A) more products and fewer reactants.
B) more reactants and fewer products.
C) more reactants and products.
D) fewer reactants and products.
E) no change in the quantities of reactants and products.

A) whenever it simplifies the calculation
B) whenever it is very much smaller than the term it is added to or subtracted from
C) whenever the equilibrium concentration for that species is relatively very small
D) whenever it is raised to any power higher than 1
E) never

A) Yes, the concentration is much greater than K, so the x can be ignored.
B) Yes, the value of x determined in this way is less than 0.05, so it can be ignored.
C) No, the value of x determined in this way significantly reduces the denominator.
D) No, the value of x can never be ignored in solving an algebra problem.
E) No, the value of K is much less than 1, so x cannot be ignored.

A) 0.50 M
B) 0.37 M
C) 0.63 M
D) 1.0 M
E) 0.19 M

A) I only
B) II only
C) III only
D) IV only
E) III and IV

A) [H₂] = [I₂] = 0.023 M, [HI] = 0.046 M
B) [H₂] = [I₂] = 0.0069 M, [HI] = 0.046 M
C) [H₂] = [I₂] = [HI] = 0.023 M
D) [H₂] = [I₂] = 0.0069 M, [HI] = 0.023 M
E) [H₂] = [I₂] = 0.23 M, [HI] = 0.46 M

A) 1.9 atm
B) 1.4 atm
C) 0.84 atm
D) 0.29 atm
E) 0.57 atm

A) Only the forward rate increases, so the quantity of products increases.
B) Only the forward rate increases, but the quantity of products remains the same.
C) Both the forward and reverse rates increase, and the quantity of products increases.
D) Both the forward and reverse rates increase, but the quantity of products is unchanged.
E) The effect varies depending on whether the reaction is endothermic or exothermic.

A) Yes, there will be more NO₂ at higher pressures.
B) Yes, there will be less NO₂ at higher pressures.
C) No, the amount of NO₂ has nothing to do with pressure.
D) No, the amount of NO₂ depends on the partial pressure, not the total pressure.
E) There is no way to tell without additional information.

A) -x, -x, +x.
B) +x, +x, -x.
C) -x, -4x, +x.
D) +x, +4x, +x.
E) +x, +4x, -x.

A) $x = \left\{ \frac { b + c } { a } \right\} \frac { 1 } { 2 }$
B) $a x ( x + b ) = - c$
C) $x = \frac { \left\{ - b \pm \left( b ^ { 2 } - 4 a c \right) \right\} } { 2 a }$
D) $x = \frac { \left\{ - b \pm \left( b ^ { 2 } - 4 a c \right) ^ { 1 / 2 } \right\} } { 2 a }$
E) $x = \frac { \left\{ - b \pm \left( b ^ { 2 } - 4 a c \right) \right\} ^ { 1 / 2 } } { 2 a }$

A) Q would increase and K would stay the same.
B) Q would decrease and K would stay the same.
C) Q would stay the same and K would increase.
D) Q would stay the same and K would decrease.
E) Both Q and K would stay the same.

A) 1.0 M
B) 1.0 M - x
C) 1.0 M - 3x
D) 1.0 M + 3x
E) -3x