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Enrichment - Derivation of Integrated Rate Equations. For a first-order reaction, the rate is proportional to the first power of [A]. . Enrichment - Derivation of Integrated Rate Equations.
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Enrichment - Derivation of Integrated Rate Equations • For a first-order reaction, the rate is proportional to the first power of [A].
Enrichment - Derivation of Integrated Rate Equations • In calculus, the rate is defined as the infinitesimal change of concentration d[A] in an infinitesimally short time dt as the derivative of [A] with respect to time.
Enrichment - Derivation of Integrated Rate Equations • Rearrange the equation so that all of the [A] terms are on the left and all of the t terms are on the right.
Enrichment - Derivation of Integrated Rate Equations • Express the equation in integral form.
Enrichment - Derivation of Integrated Rate Equations • This equation can be evaluated as:
Enrichment - Derivation of Integrated Rate Equations • Which rearranges to the integrated first order rate equation.
Enrichment - Derivation of Integrated Rate Equations • Derive the rate equation for a reaction that is second order in reactant A and second order overall. • The rate equation is:
Enrichment - Derivation of Integrated Rate Equations • Separate the variables so that the A terms are on the left and the t terms on the right.
Enrichment - Derivation of Integrated Rate Equations • Then integrate the equation over the limits as for the first order reaction.
Enrichment - Derivation of Integrated Rate Equations • Which integrates the second order integrated rate equation.
Enrichment - Derivation of Integrated Rate Equations • For a zero order reaction the rate expression is:
Enrichment - Derivation of Integrated Rate Equations • Which rearranges to:
Enrichment - Derivation of Integrated Rate Equations • Then we integrate as for the other two cases:
Enrichment - Derivation of Integrated Rate Equations • Which gives the zeroeth order integrated rate equation.
Enrichment - Rate Equations to Determine Reaction Order • Plots of the integrated rate equations can help us determine the order of a reaction. • If the first-order integrated rate equation is rearranged. • This law of logarithms, ln (x/y) = ln x - ln y, was applied to the first-order integrated rate-equation.