Answer : The order of reaction is 2 (second order) and the rate law is, [tex]R=k[AB]^2[/tex]
Explanation :
As the expression of rate is,
[tex]R=k[AB]^n[/tex]
where,
R = rate
k = rate constant
[AB] = concentration of AB
n = order of the reaction
First we have to calculate the rate for 0.200 mol/L 'AB' concentration with initial rate 0.00320 mol/L.s
[tex]R_1=k[AB_1]^n[/tex]
[tex]0.00320=k(0.200)^n[/tex] .............(1)
Now we have to calculate the rate for 0.400 mol/L 'AB' concentration with initial rate 0.0128 mol/L.s
[tex]R_2=k[AB_2]^n[/tex]
[tex]0.0128=k(0.400)^n[/tex] .............(2)
Now dividing the equation 1 by equation 2, we get the order of reaction.
[tex]\frac{0.00320}{0.0128}=\frac{k(0.200)^n}{k(0.400)^n}[/tex]
By solving the term, we get the value of 'n'.
n = 2
Thus, the order of reaction = n = 2
The rate law will be,
[tex]R=k[AB]^2[/tex]
So we conclude that,
For n = 0, the rate law will be zero order.
For n = 1, the rate law will be first order.
For n = 2, the rate law will be second order.
and so on.....
Hence, the order of reaction is 2 (second order) and the rate law is, [tex]R=k[AB]^2[/tex]
