The reaction A --> Products is second order with a rate constant of 0.2500 L mol-1 s-1. If we start with a 1.000 M concentration of A, what is the rate of the reaction (in mol L-1 s-1) after 20 s? Your answer should be rounded up to four decimal places.
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The reaction A --> Products is second order with a rate constant of 0.2500 L mol-1...
The second-order rate constant for the following gas-phase reaction is 0.048 1/MLaTeX: \cdot⋅s. We start with 0.136 mol C2F4 in a 2.47 liter container, with no C4F8 initially present. C2F4 LaTeX: \longrightarrow⟶ 1/2 C4F8 What will be the concentration of C2F4 after 1.61 hours? Enter to 4 decimal places.
The second-order rate constant for the following gas-phase reaction is 0.043 1/M?s. We start with 0.497 mol C2F4 in a 2.23 liter container, with no C4F8 initially present. C2F4 ? 1/2 C4F8 What will be the concentration of C4F8 after 2.17 hours? Enter to 4 decimal places. HINT: You will need to figure out how much of C2F4 was used (that is the only material that can be converted to the product).
At a given temperature a second order reaction has a rate constant of 146 L/mol*s and an initial concentration of 0.10M. How long will it take to be 85% complete?
The rate constant of the second order reaction A→4B+2C is 0.599 L mol−1 s−1. What is the half-life of the reaction given that [A] 0 =0.567 mol L−1? Remember to report your answer with the correct number of significant figures.
The rate constant of the second order reaction 4A→3B+4C is 0.699 L mol −1 s −1 . What is the half-life of the reaction given that [A] 0 =0.631 mol L −1 ?
Kinetics. The rate constant for a particular second-order reaction is 0.47 M-1s-1. If the initial concentration of reactant is 0.25 mol/L, what concentration will remain after 12.0 s? SHOW ALL WORK - SHOW ALL STEPS (WITH UNITS)
The rate constant for this second-order reaction is 0.430 M-'.s at 300 °C. A- products How long, in seconds, would it take for the concentration of A to decrease from 0.670 M to 0.310 M? 1 = 6.355 Incorrect Calculate the rate constant, k, for a reaction at 56,0 °C that has an activation energy of 88.6 kJ/mol and a frequency factor of 6.85 x 10's-1 k= 2.2188 SI Incorrect
1. The second-order rate constant for self-reaction of hydroxyl radicals 2 OH → H2O + O has the value 1.0786E9 M-1·s-1 at 360.0 K. Compute the half-life of OH radicals at this temperature if the initial concentration is 6.74E-6 M. 3. Calculate the initial rate of a first-order reaction if the concentration of reactant is 0.37 M and the half-life is 4.48 s. Enter the correct numerical value to 2.0% precision. Express scientific notation like 4.29E-15 M·s-1 4. Cyano...
The rate constant for this second‑order reaction is 0.300 M−1⋅s−1 at 300 degrees C. A⟶products How long, in seconds, would it take for the concentration of A to decrease from 0.630 M to 0.300 M
A certain second-order reaction (B→products) has a rate constant of 1.20×10−3 M−1⋅s−1 at 27 ∘C and an initial half-life of 260 s . What is the concentration of the reactant B after one half-life?