Academic Integrity: tutoring, explanations, and feedback — we don’t complete graded work or submit on a student’s behalf.

The integrated rate laws for zero-, first-, and second-order reaction may be arr

ID: 983933 • Letter: T

Question

The integrated rate laws for zero-, first-, and second-order reaction may be arranged such that they resemble the equation for a straight line,y=mx+b.

1) The reactant concentration in a zero-order reaction was 6.00×102M after 150 sand 3.50×102M after 330 s . What is the rate constant for this reaction? Express your answer with the appropriate units.

2) What was the initial reactant concentration for the reaction described in Part A? Express your answer with the appropriate units.

3) The reactant concentration in a first-order reaction was 9.20×102 M after 50.0 s and 7.50×103 M after 60.0 s . What is the rate constant for this reaction? Express your answer with the appropriate units.

4) The reactant concentration in a second-order reaction was 0.440 M after 180 s and 5.70×102 M after 860 s . What is the rate constant for this reaction? Express your answer with the appropriate units. Include an asterisk to indicate a compound unit with mulitplication, for example write a Newton-meter as N*m.

Order Integrated Rate Law Graph Slope 0 [A]=kt+[A]0 [A] vs. t k 1 ln[A]=kt+ln[A]0 ln[A] vs. t k 2 1[A]= kt+1[A]0 1[A] vs. t k

Explanation / Answer

We use given integrated rate laws.

1)

Initial concentration of reactant = 6.00 E-2 M , After 150 second , 3.50 E-2 M

After 330 s

We use initial concentration [A]0 = 6.00 E-2 M , and final concentration [A]t = 3.50 E-2

Here T = 330 s – 150 s = 180 s

[A]t = -kt + [A]0

k =- ([A]t - [A]0 ) / t

k = -(3.50E-2 – 6.0 E-2)/ 180 s

= 1.4 E-4 per s

Or 1.4 E-4 s-1

2)

Here we find the concentration of reactant at time = 0 s

[A]t = -kt + [A]0

We use concentration of At at t = 150 s

[A]0 = [A]t +kt

= 6.00 E-2 M + (1.4 E-4 per s x 150 s )

= 8.1 E-2 M

3)

We use first order integrated rate equation.

Ln ([A]t /[A]0 =-kt

[A]0 = 9.20 E-2 , t = 50.0 s

[A]t = 7.50 E-2 M at 860 s    so time for decomposition = 860 – 50.0 = 630 s

Ln ([A]t /[A]0 =-kt

ln ( 7.50 E-2 / 9.20 E-2) = - k x 630 s

k = 3.24 E -4 S-1

4)

[A]t = 5.70 E-2 M   [A]0 = 0.440 M  

t = 680 – 180 = 730 s

We use integrated second law for it.

1[A] = kt + [A]0

5.70 E-2 = k x 730 + 0.440

k = 4.7E-4 s^-1

Related Questions

The instructions were : Write a Temperature class using the Demo below. The clas
Question #3812160
The instructor in one of your classes distributed a syllabus that includes the f
Question #430120
The instructor never taught the class how to solve this question. Not only the a
Question #188086
The instructor provided Assignment5 but there are gaps in the code and those gap
Question #3664761
The instructor want us to write a program that can re displays the menu only whe
Question #3538626
The instructor will Illustrate how concentration measurements are made using a S
Question #503840
The instructors need help rewriting their gradesheet generation program in Perl.
Question #3538661
The instrument that is used to measure the optical activity of a compound is cal
Question #893109
Hire Me For All Your Tutoring Needs
Integrity-first tutoring: clear explanations, guidance, and feedback.
Drop an Email at
drjack9650@gmail.com
Chat Now And Get Quote

Navigate

Previous
The integrated rate laws for zero-, first-, and second-order reaction may be arr
Next
The integrated rate laws for zero-, first-, and second-order reaction may be arr

Integrity-first tutoring: explanations and feedback only — we do not complete graded work. Learn more.