113. In this chapter we have seen a number of reactions in which a single reactant forms products. For example, consider the fol lowing first-order reaction: CH3NC(g) -CH,CN(g) However, we also learned that gas-phase reactions occur through collisions. a. One possible explanation for how this reaction occurs is that two molecules of CH3NC collide with each other and form two molecules of the product in a single elementary step. If that were the case, what reaction order would you expect? b. Another possibility is that the reaction occurs through more than one step. For example, a possible mechanism involves one step in which the two CH3NC molecules collide, result- ing in the "activation" of one of them. In a second step, the activated molecule goes on to form the product. Write down this mechanism and determine which step must be rate determining in order for the kinetics of the reaction to be first order. Show explicitly how the mechanism predicts first order kinetics.

1. In order for a chemical reaction to occur, which of the following has to happen? a. molecules must have enough energy b. molecules must collide c. molecules must collide with the proper orientation d. all of the above 2. How many molecules react in a termolecular process? a. b. 2 C. d. 4 3. What step is the rate-determining step in a reaction mechanism? __ a. the slow step b. the fast step c. the first step d. the last step 4. What does a catalyst do to an equilibrium? causes products to be favored b. a. causes reactants to be favored speeds up only the forward reaction d. c. nothing 5. Rate laws are determined by a. looking at the balanced chemical equation b. the number of steps in the reaction mechanism c. experiment d. foolish people (i.e. chemists) who have nothing better to do True (+) or False (0) (2 pts each) 6. Most collisions between molecules do result in a reaction. 7. Increasing the surface tension causes an increase in the reaction rate. 8. If the temperature of a reaction is increased by 20°C, the reaction rate will approximately quadruple. 9. The rate constant, k, has the same value at all temperatures. 10. The rate constant, k, has the same value for all reactions. 11. If the equilibrium constant, K, is very small, products are favored. 12, Kc= Kp 13. A bimolecular process requires a total of two moles of reactants.

The following elementary steps are determined to be the mechanism of a given reaction: Step 1 (slow): A+ B rightarrow'C + D Step 2 (fast): C rightarrow E Step 3 (fast): E + A rightarrow 3B + F a. What is the overall reaction? A + B rightarrow C + D 2A + B + 2C + E rightarrow 3B + C + D + E + F 2A rightarrow 2B + D + F A + B + C rightarrow B + D + E + F A + B rightarrow 3B + F b. Which species is/are intermediate(s)? (If more than one species are intermediates, enter them separated by a single space.) c. What is the rate law for step 1 of this mechanism? (Do not use spaces in your answer. For zero order, don't include the reactant: for first order, don't include the order.) rate = d. What is the rate law for step 3 of this mechanism? (Do not use spaces in your answer For zero order, don't include the reactant, for first order, don't include the order) rate = e. What is the molecularity of step 1? f What is the rate law for the overall reaction?(Do not use spaces in your answer. For zero order, don't include the reactant, for first order, don't include the order.) rate =

Complete the mechanism for the reaction of butanone with NaBH4 in methanol. We will treat the NaBH4 as being equivalent to a hydride anion NaBH4 C, HSC (OCH Alcohol Product CHOH C aw the charged organic intermediate product of step one, tnen the final product after step 2. Include nonbonding electrons Add curved arrows to show the mechanism and charges. Show mechanism arrows for step two, in which the ionic intermediate reacts with the methanol to give the final of the first step of the reaction. product. have given the 4-carbon templates, but you need to fill out what gives with the oxygens. Step One CH3 Step Two