${\displaystyle p{\rm {A))+q{\rm {B))+\cdots \longrightarrow r{\rm {X))+s{\rm {Y))+\cdots }$

${\displaystyle v=k[{\rm {A))]^{p}[{\rm {B))]^{q}\cdots }$

${\displaystyle v'=k'[{\rm {X))]^{r}[{\rm {Y))]^{s}\cdots }$

${\displaystyle K={\frac {k}{k'))={\frac {[{\rm {X))]^{r}[{\rm {Y))]^{s}\cdots }{[{\rm {A))]^{p}[{\rm {B))]^{q}\cdots ))}$

${\displaystyle {\ce ((A}+{A}<=>[k_{1}][k_{-1}]{A^{\ast ))+{A))))$

${\displaystyle {\ce ((A^{\ast ))->[k_{2}]{X))))$

${\displaystyle [{\rm {A))^{*}]={\frac {k_{1)){k_{-1))}[{\rm {A))]}$

${\displaystyle v={\frac {\mathrm {d} [{\rm {X))]}{\mathrm {d} t))=k_{2}[{\rm {A))^{*}]={\frac {k_{2}k_{1)){k_{-1))}[{\rm {A))]}$

${\displaystyle {\rm {A+BC\longrightarrow AB+C))}$

${\displaystyle \nu =k_{\mathrm {B} }{T}/h}$

${\displaystyle k=\kappa \nu K^{\ddagger ))$

${\displaystyle K^{\ddagger }={\frac {[{\rm {A))\cdots {\rm {B))\cdots {\rm {C))^{*}]}{[{\rm {A))][{\rm {BC))]))}$

${\displaystyle {\begin{aligned}k&=\kappa \left(k_{B}{\frac {T}{h))\right)K^{\ddagger }\\&=\kappa \left(k_{B}{\frac {T}{h))\right)\exp \left(-{\frac {\Delta G^{\ddagger )){RT))\right)\\&=\kappa \left(k_{B}{\frac {T}{h))\right)\exp \left(-{\frac {\Delta H^{\ddagger )){RT))\right)\exp \left({\frac {\Delta S^{\ddagger )){R))\right)\end{aligned))}$

${\displaystyle \Delta G^{\ddagger ))$: 活性化自由エネルギー

${\displaystyle \Delta H^{\ddagger ))$: 活性化エンタルピー

${\displaystyle \Delta S^{\ddagger ))$: 活性化エントロピー