Don't use AI Reaction W has a rate constant of 2.35 x10-4 s-1 at room temperature, but has a rateconstant of 9.15 x10-4 s-1 when the reaction is heated by 5°C. Determine thereaction's activation energy and frequency factor.You are studying the kinetics of three chemical reactions. You perform each atseveral different temperatures and construct Arrhenius plots for each. The trendlinesfor each are given below.Reaction X:y = -6137.8x + 25.97Reaction Y:y = -3560.7x + 26.94Reaction Z:y=-8717.9x + 24.12a. Which of the reactions has the lowest activation energy?Reaction XReaction YReaction Zb. Which of the reactions has the highest frequency factor?Reaction XReaction YReaction Zc. Which of the reactions is second order?Reaction XReaction Ycannot be determinedcannot be determinedReaction Zcannot be determined

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Answered: Reaction W has a rate constant of 2.35…

Chemistry: The Molecular Science

5th Edition

ISBN:9781285199047

Author:John W. Moore, Conrad L. Stanitski

Publisher:John W. Moore, Conrad L. Stanitski

Chapter11: Chemical Kinetics: Rates Of Reactions

Section: Chapter Questions

Problem 77QRT

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Reaction W has a rate constant of 2.35 x10-4 s-1 at room temperature, but has a rate
constant of 9.15 x10-4 s-1 when the reaction is heated by 5°C. Determine the
reaction's activation energy and frequency factor.
You are studying the kinetics of three chemical reactions. You perform each at
several different temperatures and construct Arrhenius plots for each. The trendlines
for each are given below.
Reaction X:
y = -6137.8x + 25.97
Reaction Y:
y = -3560.7x + 26.94
Reaction Z:
y=-8717.9x + 24.12
a. Which of the reactions has the lowest activation energy?
Reaction X
Reaction Y
Reaction Z
b. Which of the reactions has the highest frequency factor?
Reaction X
Reaction Y
Reaction Z
c. Which of the reactions is second order?
Reaction X
Reaction Y
cannot be determined
cannot be determined
Reaction Z
cannot be determined

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