front 1 Consider the reaction: 2O3(g) 3O2(g) rate = k[O3]2[O2]-1 What is the overall order of the reaction and the order with respect to [O3]? | back 1 1 and 2 The exponent of [O3] in the rate law is 2. So, the reaction is second order with respect to [O3]. Adding the exponents together, we get: 2 + (-1) = 1 So, the reaction is first order overall. |
front 2 When the reaction below: 3NO(g) N2O(g) + NO2(g) is proceeding under conditions such that 0.015 mol/L of N2O is being formed each second, the rate of the overall reaction is ________ and the rate of change for NO is ________. | back 2 0.015 M/s; -0.045 M/s Notice that three moles of NO are required to make one mole of N2O in this reaction. So, the rate of disappearance of NO (which has a negative sign) is THREE times the rate of appearance N2O. As the coefficient of N2O is a ONE, the rate of its appearance matches the rate of the overall reaction. |
front 3 What is the rate law for the reaction below: A + B + C D if the following data were collected? Exp [A]0 [B]0 [C]0 Initial Rate | back 3 rate = 3.36x10-3 [A] [B]3 The general form of the rate law has to be: rate = k [A]x [B]y [C]z Using the experiments given to set up several equations, we get: 2.32x10-3 = k(0.4)x(1.2)y(0.7)z 7.54x10-3 = k(1.3)x(1.2)y(0.9)z 9.25x10-2 = k(0.4)x(4.1)y(0.8)z 7.54x10-3 = k(1.3)x(1.2)y(0.2)z With algebra, we find x=1, y=3, and z=0. Plugging these values in, we get the rate law as: rate = k [A] [B]3 [C]0 = k [A] [B]3 We can now plug in any experiment into the rate law above to solve for k. Plugging in experiment 1: 2.32x10-3 = k(0.4)(1.2)3 k = 3.36x10-3 The complete rate law: rate = 3.36x10-3 [A] [B]3 |
front 4 A chemical reaction is expressed by the balanced chemical equation: A + 2B C Consider the data below: exp [A]0 [B]0 initial rate (M/min) Find the rate law for the reaction. | back 4 rate = k [A] [B]2 The general form of the rate law has to be: rate = k [A]x [B]y Using the experiments given to set up several equations, we get: 0.00110363 = k(0.15)x(0.15)y 0.0044145 = k(0.15)x(0.3)y 0.008829 = k(0.3)x(0.3)y With algebra, we find x=1 and y=2. Plugging these values in, we get the rate law as: rate = k [A]1 [B]2 = k [A] [B]2 |
front 5 Calculate the value of the rate constant (k) for the reaction in question above | back 5 0.327 Any of the three experimental data sets can then be plugged in to solve for k. Plugging in the first experiment: 0.00110363 = k(0.15)(0.15)2 k = 0.327 |
front 6 If the initial concentrations of both A and B are 0.31 M for the reaction in questions 4 and 5, at what initial rate is C formed? | back 6 rate = 0.327 [A] [B]2 r ate = 0.327(0.31)(0.31)2 = 0.00974 M/min |
front 7 We know that the rate expression for the reaction below: 2NO + O2 2NO2 at a certain temperature is rate = [NO]2 [O2]. We carry out two experiments involving this reaction at the same temperature, but in the second experiment the initial concentration of NO is doubled while the initial concentration of O2 is halved. The initial rate in the second experiment will be how many times that of the first? | back 7 2 Let's say that [NO] = x and [O2] = y in the first reaction. Therefore, in the second reaction, [NO] = 2x and [O2] = 0.5y. If rate = k [NO]2 [O2]... First reaction: rate = kx2y Second reaction: rate = k(2x)2(0.5y) = 2kx2y Therefore, the initial rate in the second experiment will be two times that of the first. |
front 8 Consider the data collected for a chemical reaction between compounds A and B that is first order in A and first order in B: rxn [A]0 [B]0 rate (M/s) From the information above for 3 experiments, determine the missing concentrations of A and B. Answers should be in the order [A] then [B]. | back 8 0.80M : 0.20M Use trial 1 to determine the rate constant k. rate = k[A][B] = k(0.2)(0.05) = 0.1 k = 10 M-1·s-1 Using trial 2, solve for [A]: rate = 10(x)(0.05) = 0.4 x = 0.8 M Using trial 3, solve for [B]: rate = 10(0.4)(y) = 0.8 y = 0.2 M |
front 9 For a reaction that is zero-order overall... | back 9 the rate does not change during the reaction. Remember that for a zero-order reaction, the reactant is still used up. Its concentration will decrease as time passes, but the rate will not be affected. The rate will also not change for a zero-order reaction if you double or triple the concentration of that reactant. |
front 10 Consider the reaction below: A + B C If it is 1st order in A and 0th order in B, a plot of ln[A] vs time will have a slope that is... | back 10 Constant The first order integrated rate equation shows a linear relationship between the natural log of concentration and time. |
front 11 Consider the reaction below: H2CO3(aq) CO2(aq) + H2O(l) If it has a half-life of 1.6 sec, how long will it take a system with [H2CO3]0 of 2M to reach [H2CO3] of 125mM? | back 11 4 |
front 12 At a certain fixed temperature, the reaction below: A(g) + 2B(g) AB2(g) is found to be first order in the concentration of A and zeroth order in the concentration of B. The reaction rate constant is 0.05s-1. If 2.00 moles of A and 4.00 moles of B are placed in a 1.00 liter container, how many seconds will elapse before the concentration of A has fallen to 0.30 moles/liter? | back 12 37.94 rate = k[A] ln[A] = ln[A]0 - kt [A]0 = 2.00 mol / 1.00 liter = 2 M [A] = 0.3 M \ln\left(0.3\:M\right)\:=\:\ln\left(2M\right)-\left(0.05\:s^{-1}\right)t t = 37.94 sec |
front 13 The reaction below: A >>>>> products is observed to obey first-order kinetics. Which of the following plots should give a straight line? | back 13 ln[A] vs t The first order integrated rate equation is ln[A] = ln[A]0 - kt Since k and ln[A]0 are constants, this equation is in the form y = b + mx, where y = ln[A] and x = t. A straight line is produced by this equation. |
front 14 For the reaction below: cyclobutane(g) >>>>>>>>> 2ethylene(g) at 800K, a plot of ln[cyclobutane] vs t gives a straight line with a slope of -1.6 s-1. Calculate the time needed for the concentration of cyclobutane to fall to 1/16 of its initial value. | back 14 1.7 sec |
front 15 The initial concentration of the reactant A in a first-order reaction is 1.2 M. After 69.3 sec, the concentration has fallen to 0.3 M. What is the rate constant k? | back 15 0.02 s-1 |
front 16 A reaction is found to be first order with respect to one of the reactant species, A. When might a plot of ln[A] vs time NOT yield a straight line? | back 16 All the answers could be correct If a reaction is first order with respect to species A, a plot of ln[A] vs time will yield a straight line only if the reactions is zeroth order with respect to all other species (first order overall) or if the concentrations of the other species is effectively constant (pseudo-first order). Additionally, the reaction should not come to equilibrium, as this will mean that the forward rate and backward rates are equal. At this point, the reaction rate will level off to a constant value. This is the same as having a significant backwards reaction. |
front 17 Consider the following elementary reactions: a) NO + O3 NO2 + O2 b) CS2 CS + S c) O + O2 + N2 O3 + N2 Identify the molecularity of each reaction respectively. | back 17 bimolecular, unimolecular, termolecular The elementary reactions given have two reactants, one reactant, and three reactants respectively. Therefore, they are bimolecular, unimolecular, and termolecular respectively. |
front 18 A and B react to form C according to the single step reaction below: A + 2B C Which of the following is the correct rate equation for [B] and the correct units for the rate constant of this reaction? | back 18 no data |
front 19 Consider the mechanism below: NO2 + F2 NO2F + F k1, slow F + NO2 NO2F k2, fast What is the rate law? | back 19 no data |
front 20 Determine the overall balanced equation for a reaction having the following proposed mechanism: Step 1: B2 + B2 E3 + D slow Step 2: E3 + A B2 + C2 fast and write an acceptable rate law. | back 20 no data |
front 21 Consider the reaction below: H2(g) + I2(g) 2HI(g) The proposed mechanism of this reaction is: I2 ⇌ 2I k1, k-1(reverse rxn), fast 2I + H2 2HI k2, slow What is the rate of the overall reaction? | back 21 no data |
front 22 A reaction rate increases by a factor of 655 in the presence of a catalyst at 37°C. The activation energy of the original pathway is 106 kJ/mol. What is the activation energy of the new pathway, all other factors being equal? | back 22 no data |