lodine, k, is reacted with cyclohexanone, CeH100, and the chemical equation is as following: The reaction rate can be expressed as following: A(I,1 K[H']'[cyclohexanone]L,T Δ rate Chemicals HCI Cyclohexanone Distilled water Triodide, Initial concentration, M 5x 10 3x 10 4 x 102 Determine the concentrations of HCI, cyclohexanone, and triodide in this solution. Chemicals Volume added, mL Concentration in solution, M HCI Cyclohexanone Water Triiodide, Total volume, mL 16 18 12 50 The rate orders for H, CaH100, and 1, are 1, 1 and 0, respectively. The kinetic studies of the prepared solution are analyzed in two different temperatures, which are 30°C and 40°C. Triiodide decolorized at 16 minutes and 10 minutes at reaction temperatures of 30°C and 40°C, respectively. Calculate the concentrations of HCI, cyclohexanone, and triodide in the prepared solution. a Calculate the rates of reaction at 30°C and 40°C, respectively.

please help me with question a and b only

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lodine, k, is reacted with cyclohexanone, CeH100, and the chemical equation is as following: The reaction rate can be expressed as following: A[L,] K[H*][cyclohexanonejLT Δι rate - Chemicals HCI Cyclohexanone Distilled water Triiodide, Initial concentration, M 5x 101 3x 101 4 x 102 Determine the concentrations of HCI, cyclohexanone, and triodide in this solution. Chemicals Volume added, mL 16 Concentration in solution, M HCI Cyclohexanone Water Triiodide, Total volume, mL 18 12 4 50 The rate orders for H", CaH100, and , are 1, 1 and 0, respectively. The kinetic studies of the prepared solution are analyzed in two different temperatures, which are 30°C and 40°C. Triiodide decolorized at 16 minutes and 10 minutes at reaction temperatures of 30°C and 40°C, respectively. Calculate the concentrations of HCI, cyclohexanone, and triodide in the prepared solution. a Calculate the rates of reaction at 30°C and 40°C, respectively. Calculate the rate constants for reactions at 30°C and 40°C, respectively. Calculate the activation energy with Arrhenius equation. O°C = 273 K; gas constant, R = 8.314 J/mol-K. d k, E, T, - T, In R( T,T, k,