What is the derivation for the half life of a second order reaction with: (i) equal concentration of reactants for the reaction $2 A \to product$ $2A -> "product"$ (ii) unequal concentration of reactants for the reaction $A + B \to product$ $A + B -> "product"$ ?

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What is the derivation for the half life of a second order reaction with: (i) equal concentration of reactants for the reaction $2 A \to product$ $2A -> "product"$ (ii) unequal concentration of reactants for the reaction $A + B \to product$ $A + B -> "product"$ ?

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Answer 1 · 2015-12-01T18:49:39

(i) $A + A \to P$ $A + A -> P$

What you can start with is writing out the rate law.

$r (t) = k {[A]}^{2} = \frac{d [A]}{d t}$ $r(t) = k[A]^2 = (d[A])/(dt)$

Then, with a separation of variables (where $t_{0} = 0 s$ $t_0 = "0 s"$ and $[A] = \frac{{[A]}_{0}}{2}$ $[A] = [A]_0/2$ )

$- k \int_{t}^{t_{0}} d t = \int_{{[A]}_{0}}^{[A]} \frac{1}{{[A]}^{2}} d [A]$ $-kint_(t)^(t_0) dt = int_([A]_0)^([A]) 1/[A]^2 d[A]$

$- k t = (- \frac{1}{[A]}) - (- \frac{1}{{[A]}_{0}})$ $-kt = (-1/([A])) - (-1/[A]_0)$

$- k t_{1/2} = - \frac{1}{[A]} + \frac{1}{2 [A]} = - \frac{1}{2 [A]}$ $-kt_"1/2" = -1/([A]) + 1/(2[A]) = -1/(2[A])$

$t_{1/2} = \frac{1}{2 k [A]}$ $color(blue)(t_"1/2" = 1/(2k[A]))$

(ii) $A + B \to P$ $A + B -> P$

This one is much harder, because ${[A]}_{0} \neq {[B]}_{0}$ $[A]_0 ne [B]_0$ . So... let ${[A]}_{0} = a$ $[A]_0 = a$ , ${[B]}_{0} = b$ $[B]_0 = b$ , $[A] = a - x$ $[A] = a-x$ , and $[B] = b - x$ $[B] = b-x$ .

$- \frac{d x}{d t} = - k (a - x) (b - x)$ $-(dx)/(dt) = -k(a-x)(b-x)$

$\int_{0}^{x} \frac{1}{(a - x) (b - x)} d x = \int_{t_{0}}^{t} k d t$ $int_0^x 1/((a-x)(b-x))dx = int_(t_0)^(t) kdt$

Using partial fraction decomposition (which you should know if you actually need to do this derivation for homework), and I'll skip to the answer, you get:

$\frac{1}{b - a} [ln (\frac{1}{a - x}) - ln (\frac{1}{b - x})] = k t$ $1/(b-a) [ln(1/(a-x)) - ln(1/(b-x))] = kt$

If we plug values back in and normalize the natural logarithms such that ${[A]}_{0} = 1$ $[A]_0 = 1$ :

$\frac{1}{{[B]}_{0} - {[A]}_{0}} [ln (\frac{{[A]}_{0}}{{[A]}_{0} - x}) - ln (\frac{{[A]}_{0}}{{[B]}_{0} - x})] = k t$ $1/([B]_0-[A]_0) [ln(([A]_0)/([A]_0-x)) - ln(([A]_0)/([B]_0-x))] = kt$

$ln (\frac{{[A]}_{0} [B]}{[A] {[B]}_{0}}) = k ({[B]}_{0} - {[A]}_{0}) t$ $color(blue)(ln(([A]_0[B])/([A][B]_0)) = k([B]_0-[A]_0)t)$

This is as far as you can go. You CANNOT get a half-life expression for this, because you don't know what $[A]$ $[A]$ and $[B]$ $[B]$ become. They have different half-lives, and so the half-life for the overall reaction is not able to be determined.

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What is the derivation for the half life of a second order reaction with: (i) equal concentration of reactants for the reaction $2 A \to product$ $2A -> "product"$ (ii) unequal concentration of reactants for the reaction $A + B \to product$ $A + B -> "product"$ ?

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What is the derivation for the half life of a second order reaction with: (i) equal concentration of reactants for the reaction 2A→product2A -> "product" (ii) unequal concentration of reactants for the reaction A+B→productA + B -> "product"?

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What is the derivation for the half life of a second order reaction with: (i) equal concentration of reactants for the reaction $2 A \to product$ $2A -> "product"$ (ii) unequal concentration of reactants for the reaction $A + B \to product$ $A + B -> "product"$ ?