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Jonathan Nichols edited $n^{th}$ Order Irreversible Decay.tex
over 9 years ago
Commit id: 9a538347368970d382b6c10fda6f9df62d0a9db4
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\end{equation}
As shown in equation 4, the statistical length is the integral of the cumulative time dependent rate coefficient over a period of time $\Delta{t}$. The statistical length is
\begin{equation}
\mathcal{L}(\Delta
t)^2=\left[\int_{t_i}^{t_f}\sqrt{(n-1)\omega([A]_0^{n-1})}dt\right]^2 t)^2=\left[\int_{t_i}^{t_f}(n-1)\omega([A]_0^{n-1})dt\right]^2
\end{equation}
Following length, the Fisher divergence is the integral of the cumulative time dependent rate coefficient squared over a period of time $\Delta{t}$. The Fisher divergence is
\begin{equation}