The reaction N2O5(g)→ 2 NO2 + ½ O2(g) was monitored and the following data were collected. Temperature Rate Constant (hr') 2.7x10-3 (°C) 185 165 2.9x10-4 145 2.4x10-5 125 1.4x10-6 a. Make the appropriate graph_in your calculator, Excel or Google Sheets and use that graph to determine the activation energy for the reaction. Make a rough sketch (no need to include data points) of the graph from your calculator on the axes below, being sure to label the axes. (Note: you will not earn credit for calculating the Ea without using the graphical method.) Slope of line = Ea = b. What is the equation of the line yoU used to find the activation energy? C. What is the value of the collision frequency factor, A?

The reaction N2O5(g)→ 2 NO2 + ½ O2(g) was monitored and the following data were collected. Temperature Rate Constant (hr') 2.7x10-3 (°C) 185 165 2.9x10-4 145 2.4x10-5 125 1.4x10-6 a. Make the appropriate graph_in your calculator, Excel or Google Sheets and use that graph to determine the activation energy for the reaction. Make a rough sketch (no need to include data points) of the graph from your calculator on the axes below, being sure to label the axes. (Note: you will not earn credit for calculating the Ea without using the graphical method.) Slope of line = Ea = b. What is the equation of the line yoU used to find the activation energy? C. What is the value of the collision frequency factor, A?

Chemistry

10th Edition

ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Publisher:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Chapter1: Chemical Foundations

Section: Chapter Questions

Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...

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