Using the results of the Arrhenius analysis (Eg 93.1kJ/mol and A 4.36 x 101M-s1), predict the...
Consider the following reaction: O3(g)→O2(g)+O(g) Using the results of the Arrhenius analysis (Ea=93.1kJ/mol and A=4.36×1011M⋅s−1), predict the rate constant at 308 K . Express the rate constant in liters per mole-second to three significant figures.
1. Consider the following reaction: O3(g)→O2(g)+O(g) Using the results of the Arrhenius analysis (Ea=93.1kJ/mol and A=4.36×1011M⋅s−1), predict the rate constant at 298 K . Express the rate constant in liters per mole-second to three significant figures. 2. Why is knowledge of reaction rates important (both practically and theoretically)?
Exercise 14.66 Part A Constants Periodic. Table Use an Arrhenius plot to determine the activation barrier for the reaction. Express your answer using three significant figures. data show the rate constant of a reaction 9.58x102 0.278 0.757 ??? 310 kJ/mol 4.69 Previous Answers Request Answer Incorrect; Try Again; 3 attempts remaining Part B Use an Arrhenius plot to determine frequency factor for the reaction. Express your answer using two significant figures. Submit Request Answer
HIR The following data show the rate constant of a reaction measured at several different temperatures. Use an Arrhenius plot to determine the activation barrier for the reaction. Express your answer using three significant figures. 150 ACQ* O ? Temperature (K) Rate Constant (s-1) 310 7.93x10-2 320 0.233 330 0.643 340 1.67 4.10 kJ mol-1 350 Submit Request Answer Part B Use an Arrhenius plot to determine the frequency factor for the reaction. Express your answer using two significant figures....
can anybody help me with this ? CH 5 Problem 10.33- Enhanced -with Feedback may want to reference (Pages 404-407) Section 10.4 while completing this problem. You Part A Complete the following table for an ideal gas: T V P Comple 0.490 mol ? K 2.00 atm 1.40 L Expres 32°C 0.320 atm 0.250 L ? mol ? L 0.335 mol 340 K 670 torr 565 mL 0.260 mol 295 K ? atm T Subr Part B Comple Expres Type...
Part A Find the volume occupied by 20.0 g of helium gas at 20.0 °C and 1.32 atm of pressure 0 6.22 L 0 159 L 0 24,9 L 0 91.2 L Submit Request Answer Part A Each gas sample has the same temperature and pressure. Which sample occupies the smallest volume? 0 20.0 g H, O 40.0 g Kr 40.0 g Ar O 4.0 g He Submit Request Answer Use Charles's law to complete the table. (Assume pressure and...
Consider a gas of diatomic molecules (moment of inertia I) at an absolute temperature T. If Eg is a ground-state energy and Eex is the energy of an excited state, then the Maxwell-Boltzmann distribution predicts that the ratio of the numbers of molecules in the two states is nexng=e−(Eex−Eg)/kT. The ratio of the number of molecules in the lth rotational energy level to the number of molecules in the ground-state (l=0) rotational level is nln0=(2l+1)e−l(l+1)ℏ2/2IkT. The moment of inertia of...
Exercise 11.50 Use Avogadro's law to complete the following table (assume pressure and temperature to be constant): V TV 12 25.9 L 5.08 mol 3.03 mol 1.17 mol 418 mL 0.904 mol 8.73 L 0.0023 mol 10.5 L 52 mL 12 mL 2.62x10-4 mol Part A Complete the first column of the table. Express your answer using three significant figures. 20 AED + O2 ? Vi = IL Submit Request Answer Part B Complete the second column of the table....
0.50 mol of LiNO3 in 6.10 L of solution Express your answer using two significant figures. IVO ADO ? molarity = Submit Request Answer Part B 71.1 g CH,O in 2.54 L of solution Express your answer using three significant figures. Va AS Rom ? molarity
You may want to reference (Pages 606- 612) Section 14.6 while completing this problem. The following data show the rate constant of a reaction measured at several different temperatures PartA Temperature (K) Rate constant (1/s) 300 310 320 330 340 1.61x10-2 4.90x10-2 0.139 0.370 0.931 Use an Arrhenius plot to determine the activation barrier (Ea) for the reaction Express your answer using three significant figures. kJ/mol Submit Part B Use an Arrhenius plot to determine the frequency factor (A) for...