Deck 13: Chemical Kinetics Clearing the Air

A)a catalytic intermediate
B)a photochemical inhibitor
C)a homogeneous catalyst
D)a nitrogen monoxide reducer
E)a catalytic converter

A)A catalytic converter targets compounds such as hydrocarbons, carbon monoxide, and nitrogen oxide compounds.
B)Reactions that reduce the amounts of hazardous by-products of the combustion reactions in automobiles occur very rapidly in the catalytic converter.
C)CO is usually oxidized to CO₂ in one stage of the catalytic converter.
D)N₂ is oxidized to nitrogen oxides in the catalytic converter.
E)Hydrocarbons are usually oxidized to CO₂ and H₂O in the catalytic converter.

A)in the morning before rush hour.
B)in the morning just after rush hour.
C)in midmorning.
D)at noon.
E)in midafternoon.

A)0.25 M/s
B)0.50 M/s
C)1.0M/s
D)5.0 M/s
E)10.0 M/s

A)photolytic
B)photochemical
C)photophysical
D)acidic
E)sulfurous

A)N₂
B)CO₂
C)N₂O
D)O₃
E)CO

A)NO; NO₂; O₃.
B)NO; O₃; NO₂.
C)NO₂; NO; O₃.
D)NO₂; O₃; NO.
E)O₃; NO; NO₂.

A)in the morning before rush hour
B)in the morning just after rush hour
C)midmorning
D)noon
E)midafternoon

A)stagnant air
B)sunlight
C)a lot of traffic
D)irrigation
E)cars without catalytic converters

A)The change in concentration of reactant or product is not always linear with time.
B)The average reaction rate usually decreases as the reaction proceeds.
C)The average reaction rate can be determined from the slope of a line drawn between two points on a plot of concentration versus time.
D)The average reaction rate can be determined from the slope of the tangent line drawn at time = 0 on a plot of concentration versus time.
E)The average rate usually depends on the concentrations of reactants.

A)the dashed curve
B)the gray curve
C)the black curve
D)either the gray or the black curve
E)Any of these curves could be hydrogen.

A)0.25 M/s
B)0.50 M/s
C)1.0 M/s
D)5.0 M/s
E)10.M/s

A)H₂O₂(g) + O₂(g) $\rightarrow$ O₃(g) + H₂Og)
B)N₂(g) + O₂(g) $\rightarrow$ 2 NO(g)
C)O₃(g) + NO(g) $\rightarrow$ O₂(g) + NO₂(g)
D)NO₂(g) $\rightarrow$ NO(g) + O(g)
E)N₂(g)+ 3 O₂(g) + OH(g) + CH₃CHO(g) $\rightarrow$ (CH₃O)O₂NO₂ (g) + H₂O(g) + NO₂(g)

A)0.90 M/s
B)0.45 M/s
C)0.23 M/s
D)1.0 M/s
E)0.13 M/s

A)The average rate is taken over a larger time period.
B)The instantaneous rate is taken from the slope of the curve at a specific time.
C)They are not different if the time interval chosen is small enough.
D)The instantaneous rate is always faster than the average rate.
E)Both tend to decrease as the reaction proceeds.

A)in the morning before rush hour
B)in the morning just after rush hour
C)midmorning
D)noon
E)midafternoon

A)winter
B)spring
C)summer
D)fall
E)No season should have more advisories than another.

A)0.13 M/s
B)0.50 M/s
C)1.0 M/s
D)2.0.M/s
E)5.M/s

A)Reaction rates can be measured by monitoring how much product is generated or how much reactant is consumed in a given amount of time.
B)Reaction rates can be completely predicted based on the stoichiometry of a reaction.
C)The reaction rate determined at one instant during the course of a reaction is the same as at any other instant.
D)Experimentally determined reaction rates do not depend on factors other than concentration.
E)The average rate of reaction does not vary.

A)0.420 atm
B)0.105 atm
C)0.156 atm
D)0.0704 atm
E)0.084 atm

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

A)(-2.5 * 10^-2 M/s.)
B)(-2.1* 10^-2 M/s.)
C)(-4.1 *10^-3 M/s.)
D)(-3.0 *10^-3 M/s.)
E)(-5.8 *10^-4 M/s.)

A)Higher concentrations of reactants typically lead to greater reaction rates because a larger number of effective molecular collisions occur.
B)Collisions between product molecules that reform reactant molecules do not affect the overall rate of reaction.
C)The actual dependence of reaction rate on concentration must be determined experimentally because it depends on the reaction mechanism.
D)At t = 0, the maximum rate should be observed because only reactant molecules are present.
E)As the reaction proceeds, fewer reactant molecules are present and the reaction rate typically decreases.

A)(-R(H₂) = 2/3 R(NH₃); -R(N₂) = 1/2 R(NH₃))
B)(-RH₂) = 3/2 R(NH₃); -R(N₂) = 2 R(NH₃))
C)(-R(H₂) =3/2 R(NH₃); -R(N₂)= 1/2 R(NH₃)
D)(-R(H₂)= 2/3 R(NH₃); -R(N₂) = 2 R(NH₃))
E)(-R(H₂) =R(NH₃); -R(N₂) = R(NH₃))

A)0.750 M
B)1.00 M
C)1.50 M
D)2.00 M
E)3.00 M

A)first.
B)second.
C)zero.
D)one-half.
E)third.

A)double.
B)triple.
C)stay the same.
D)increase by a factor of five.
E)decrease by a factor of one-fifth.

A) $\frac{\Delta[\mathrm{C}]}{\Delta t}=\frac{2}{5} \frac{\Delta[\mathrm{B}]}{\Delta t}$

B) $\frac{\Delta[\mathrm{B}]}{\Delta t}=\frac{5}{4} \frac{\Delta[\mathrm{D}]}{\Delta t}$

C) $\frac{\Delta[\mathrm{D}]}{\Delta t}=\frac{4}{3} \frac{\Delta[\mathrm{A}]}{\Delta t}$

D) $\frac{\Delta[\mathrm{A}]}{\Delta t}=\frac{3}{5} \frac{\Delta[\mathrm{B}]}{\Delta t}$

E) $\frac{\Delta[\mathrm{B}]}{\Delta t}=-\frac{3}{5} \frac{\Delta[\mathrm{A}]}{\Delta t}$

A)0.2 M/s
B)0.01 M/s
C)0.02 M/s
D)0.1 M/s
E)0.04 M/s

A)first.
B)second.
C)one-quarter.
D)one-half.
E)third.

A)(- $\Delta$ [A]/ $\Delta$ t increases while $\Delta$ [B]/ $\Delta$ t decreases.)
B)(- $\Delta$ [A]/ $\Delta$ t decreases while $\Delta$ [B]/ $\Delta$ t increases.)
C)Both- $\Delta$ [A]/ $\Delta$ t and $\Delta$ [B]/ $\Delta$ t decrease.
D)Both- $\Delta$ [A]/ $\Delta$ t and $\Delta$ [B]/ $\Delta$ t increase.
E)The answer will vary depending on the reaction mechanism.

A)about 1.4 times faster
B)about 1.4 times slower
C)about 2.64 times slower
D)about 2.6 times faster
E)The average rate is constant.

A)one-half
B)first
C)second
D)third
E)three-halves

A)double.
B)quadruple.
C)decrease by a factor of one-fourth.
D)decrease by a factor of one-half.
E)remain the same.

A)first.
B)second.
C)one-quarter.
D)one-half.
E)third.

A)0.275 M/s
B)0.138 M/s
C)0.0117 M/s
D)0.00917 M/s
E)0.0183 M/s

A)first
B)second
C)third
D)fourth
E)zero

A)the reactant concentrations.
B)the stoichiometric coefficients.
C)the product concentrations.
D)experimentation.
E)the difference between the forward and reverse rates.

A)first
B)second
C)third
D)fourth
E)zero

A)1.75 * 10^-4 M/s
B)3.36 * 10^-4 M/s
C)6.50 * 10^-4 M/s
D)1.01 * 10^-5 M/s
E)8.01 * 10^-5 M/s

A)0.0252 s
B)1.24 s
C)12.4 s
D)24.9 s
E)39.7 s

A)one-half
B)first
C)second
D)three-halves
E)third

A)0.350 M/s
B)0.140 M/s
C)0.035 M/s
D)0.175 M/s
E)0.070 M/s

A)6.93 s^-1
B)0.693 s^-1
C)0.0693 s^-1
D)0.144 s^-1
E)3.01 s^-1

A)first
B)second
C)third
D)three-halves
E)fourth

A)k[NO][Cl₂]
B)k[NO][Cl₂]²
C)k[NO]²[Cl₂]
D)k[NO]²[Cl₂]²
E)k[NO][Cl₂]^1/2

A)0.588 s^-1
B)0.0468 s^-1
C)0.0138 s^-1
D)0.0344 s^-1
E)0.680 s^-1

A) $\frac{3} {2}$ ; 0; $\frac{3} {2}$

B) $\frac{3} {2}$ ; 1;1

C) $\frac{3} {2}$ ; 1; $\frac{5} {2}$

D) $\frac{3} {2}$ ; 1; $\frac{7} {2}$

E)The orders cannot be determined without a chemical reaction.

A) $\frac{1} {2}$ ;0 ; $\frac{1} {2}$

B) $\frac{1} {2}$ ; 1; 1

C) $\frac{1} {2}$ ; 1; $\frac{3} {2}$

D) $\frac{1} {2}$ ; 1; $\frac{5} {2}$

E)The orders cannot be determined without a chemical reaction.

A)The rate constant is independent of temperature.
B)The units of the rate constant depend on the stoichiometry of the reaction.
C)The rate constant typically depends on concentration of reactants).
D)The rate typically depends on concentration of reactants).
E)The rate constant does not change when a catalyst is introduced.

A)M ^-1 s
B)M s^-1
C)M ^-1 s^-1
D)M ^-2 s^-1
E)M s

A)4.98 *10^-3 s
B)201 s
C)3.45 * 10^-3 s
D)100.0 s
E)1.73* 10^-3 s

A)first
B)second
C)third
D)fourth
E)zero

A)M ^-1 s^-1
B)M s^-1
C)M ^-2 s^-1
D)M ^-3 s^-1
E)s^-1

A)one-half
B)first
C)second
D)third
E)three-halves

A)the concentrations of A and B are both small.
B)the concentration of one of the reactants does not change.
C)the concentration of C is large.
D)the concentrations of A and B are both large.
E)a catalyst changes the mechanism to a first-order reaction.

A)0.828 M
B)0.201 M
C)1.00 M
D)1.21 M
E)0.350 M

A)first.
B)second.
C)third.
D)zero.
E)fourth.

A)zero-order reactions
B)first-order reactions
C)second-order reactions
D)reactions with fractional orders
E)photochemical reactions

A)1.07 minute
B)5.07 minutes
C)13.2 minutes
D)14.6 minutes
E)24.4 minutes

A)0.00534 M^-1s^-1
B)0.589 M^-1s^-1
C)0.545 M^-1s^-1
D)0.0214 M^-1s^-1
E)0.0231 M^-1s^-1

A)0.460 minute
B)2.84 minutes
C)4.40 minutes
D)7.63 minutes
E)8.94 minutes

A)2.00 F*10^-3 M ^-1 s^-1
B)1.27 * 10^-3 M ^-1 s^-1
C)3.61* 10^-5 M ^-1 s^-1
D)0.111 M ^-1 s^-1
E)6.67 M ^-1 s^-1

A)5.00 minutes
B)7.50 minutes
C)15.0 minutes
D)20.0 minutes
E)30.0 minutes

A)5.54 * 10^-9 s
B)1.24* 10^-7 s
C)1.39 * 10^-10 s
D)1.81 F*10^-10 s
E)8.09 * 10^-12 s

A)0.474 minute
B)0.592 minute
C)2.08 minutes
D)4.22 minutes
E)4.74 minutes

A)the energy of collisions.
B)the orientation of colliding molecules.
C)the energy of collisions and the orientation of colliding molecules.
D)the change in energy between the products and the reactants.
E)the change in free energy between the reactants and the products.

A)collision energy.
B)kinetic energy.
C)potential energy.
D)activation energy.
E)thermodynamic energy.

A)k[H₂][ICl]
B)k[H₂][ICl]²
C)k[H₂]²[ICl]
D)k[H₂]^1/2[ICl]^1/2
E)k[H₂][ICl]^1/2

A)1650 years
B)51,400 years
C)29,900 years
D)2,870,000 years
E)9220 years

A)9.47 M
B)0.270 M
C)0.0371 M
D)0.371 M
E)3.29 M

A)1.83 min
B)4.55 min
C)7.00 min
D)20.7 min
E)31.9 min

A)997 s
B)332 s
C)100 s
D)277 s
E)6.93 s

A)1.13 M ^-2s^-1
B)9.44 M ^-2s^-1
C)37.8 M ^-2s^-1
D)0.0265 M ^-2s^-1
E)59.6 M ^-2s^-1

A)100 s
B)120 s
C)4.79 s
D)72.2 s
E)86.6 s

A)4.65 * 10^-11 M
B)8.80 *10^-4 M
C)2.17 F* 10¹² M
D)1.39 *10^-10 M
E)4.62 * 10^-13 M

A)0.273 s
B)1.27 s
C)3.67 s
D)3.40 s
E)86.6 s

A)1.03 * 10⁶ M ^-1 s^-1
B)9.70 * 10^-8 M^-1 s^-1
C)3.49 * 10^-2 M ^-1 s^-1
D)2.86 * 10⁴ M ^-1 s^-1
E)9.70 * 10^-6 M ^-1 s^-1

A)1.65 * 10^-5 torr^-1s^-1
B)6.06 * 10⁴ torr^-1s^-1
C)8.17 *10^-5 torr^-1s^-1
D)1.34 torr^-1s^-1
E)3.48*10³ torr^-1s^-1