Answer:
First Order reaction
k= 0.0067
Explanation:
To determine the rate law we will have to study the dependence of the rate of the reaction with respect to time.
So we need to calculate the concentrations given the data since A= ε c l
where ε = molar absorptivity, c is the concentration moles/L, and l is the length of the cuvette.
c = A/εl
Time, min M, (mol/L) x 10⁻⁵
0 2.67
30 2.00
60 1.60
90 1.43
120 1.16
If the reaction were first order, the rate will have to remain constant which is not the case here since the rate of dissaperance is chnging:
Δmol/L/ΔT = (2.00 - 2.67 ) mol /30 min = -0.023 mol/Lmin ( between t= 30 and 0 min)
Δmol/L/ΔT = ( 0.160 - 2) /30 min = = -0.061 mol/Lmin
If the rate is first order we will have to use the integrated rate law:
ln (A) t = -kt + ln (A)₀
where (A) is the concentration, t is the time and k is the rate constant
Notice the equation is of the form y = mx + b where
m= rate constant and b (A)₀
To verify if our reaction is first order, we will graph the graph the data and see if it is a straght line and and if it is compute the slope which is k.
We could also perform a linear regression with an apprpiat program and obtain the results.
Working in excel the following results were obtained:
y = -0.0067 x -10.582
k = 0.0067/ min
R² = correlation coefficient = 0.979
First Order reaction
