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प्रश्न
Answer the following in brief.
Derive the integrated rate law for the first-order reaction.
उत्तर
Consider the first-order reaction,
A → product
The differential rate law is given by
rate = -`"d[A]"/"dt" = "k[A]"` ...(1)
where, [A] is the concentration of reactant at time t. Rearranging Eq. (1)
`"d[A]"/"[A]" = -"k"` dt .....(2)
Let [A]0 be the initial concentration of the reactant A at time t = 0.
Suppose [A]t is the concentration of A at time = t
The equation (2) is integrated between limits [A] = [A]0 at t = 0 and [A] = [A]t at t = t
On integration,
In`["A"]_(["A"]_0)^(["A"]_"t") = -"k" "t"_0^"t"`
Substitution of limits gives
`"In"["A"]_"t" - "In"["A"]_0 = -"kt"`
or `"In"["A"]_"t"/["A"]_0 = -"kt"` ...(3)
or k = `1/"t" "In"["A"]_0/["A"]_"t"`
Converting ln to log10, we write
k = `2.303/"t" "log"_10["A"]_0/["A"]_"t"` ...(4)
Eq. (4) gives the integrated rate law for the first-order reactions.
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