3. Determining Average, Instantaneous and Relative Rates. Use the data above to calculate the following rates using the formulas from the "Chemical Kinetics" chapter in your textbook. (a) Average Rate of disappearance of H₂O2 during the first 1000 minutes: (Set up your calculation and give answer. Include units) (b) Average Rate of appearance of O₂ during the first 1000 minutes. (Set up your calculation and give answer. Include units) (c) Use the slope of the tangent for your graph in number (2) above to determine the Instantaneous Rate of disappearance of H₂O2 at 500 minutes into the reaction. (Show your tangent on the graph and show your slope calculation with units below)
3. Determining Average, Instantaneous and Relative Rates. Use the data above to calculate the following rates using the formulas from the "Chemical Kinetics" chapter in your textbook. (a) Average Rate of disappearance of H₂O2 during the first 1000 minutes: (Set up your calculation and give answer. Include units) (b) Average Rate of appearance of O₂ during the first 1000 minutes. (Set up your calculation and give answer. Include units) (c) Use the slope of the tangent for your graph in number (2) above to determine the Instantaneous Rate of disappearance of H₂O2 at 500 minutes into the reaction. (Show your tangent on the graph and show your slope calculation with units below)
Chemistry for Engineering Students
4th Edition
ISBN:9781337398909
Author:Lawrence S. Brown, Tom Holme
Publisher:Lawrence S. Brown, Tom Holme
Chapter11: Chemical Kinetics
Section: Chapter Questions
Problem 11.20PAE: Experimental data are listed here for the reaction B: Time (s) IB] (mol/L) 0.00 0.000 10.0 0.326...
Related questions
Question
A.) is 1.3x10-5 mol/min
I need help with b and C please show your work
![2.
Making a Graph from Experimental Kinetics Data. (for the reaction below)
The decomposition of Hydrogen Peroxide is monitored in the lab.
The data in the table below shows how the H₂O₂ molarity decreases for 2000 minutes.
Plot [H₂O2₂] vs. time and attach the graph.
2 H₂O2 (aq)->2 H₂O(1) + O2(g)
Time (min)
[H₂O₂] mol/L
0
0.0200
200
0.0160
400
0.0131
600
0.0106
800
0.0086
1000
0.0069
1200
0.0056
1600
0.0037
2000
0.0024
Rev: 1.15.2020
Experiment 15 Calculations & Graphing
3.
Determining Average, Instantaneous and Relative Rates.
Use the data above to calculate the following rates using the formulas from the
"Chemical Kinetics" chapter in your textbook.
(a) Average Rate of disappearance of H₂O2 during the first 1000 minutes:
(Set up your calculation and give answer. Include units)
(b) Average Rate of appearance of O₂ during the first 1000 minutes.
(Set up your calculation and give answer. Include units)
Page 5
(c) Use the slope of the tangent for your graph in number (2) above to determine
the Instantaneous Rate of disappearance of H₂O2 at 500 minutes into the reaction.
(Show your tangent on the graph and show your slope calculation with units below)](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F9b0e7686-0c0d-4eba-ac81-54e736b47f2f%2F83a9df15-338e-4b04-9efa-6418340a1b53%2Fcrxwfiu_processed.jpeg&w=3840&q=75)
Transcribed Image Text:2.
Making a Graph from Experimental Kinetics Data. (for the reaction below)
The decomposition of Hydrogen Peroxide is monitored in the lab.
The data in the table below shows how the H₂O₂ molarity decreases for 2000 minutes.
Plot [H₂O2₂] vs. time and attach the graph.
2 H₂O2 (aq)->2 H₂O(1) + O2(g)
Time (min)
[H₂O₂] mol/L
0
0.0200
200
0.0160
400
0.0131
600
0.0106
800
0.0086
1000
0.0069
1200
0.0056
1600
0.0037
2000
0.0024
Rev: 1.15.2020
Experiment 15 Calculations & Graphing
3.
Determining Average, Instantaneous and Relative Rates.
Use the data above to calculate the following rates using the formulas from the
"Chemical Kinetics" chapter in your textbook.
(a) Average Rate of disappearance of H₂O2 during the first 1000 minutes:
(Set up your calculation and give answer. Include units)
(b) Average Rate of appearance of O₂ during the first 1000 minutes.
(Set up your calculation and give answer. Include units)
Page 5
(c) Use the slope of the tangent for your graph in number (2) above to determine
the Instantaneous Rate of disappearance of H₂O2 at 500 minutes into the reaction.
(Show your tangent on the graph and show your slope calculation with units below)
Expert Solution
Step 1
Given:
The average rate of disappearance of H2O2 during the first 1000 minutes is 1.3x10-5 mol/L min.
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