deletions | additions       diff --git a/section_Nuclear_Schottky_effect_In__.tex b/section_Nuclear_Schottky_effect_In__.tex  index 7f2b52d..4c6817a 100644  --- a/section_Nuclear_Schottky_effect_In__.tex  +++ b/section_Nuclear_Schottky_effect_In__.tex 
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where ${\mu}_0 = 4\pi \cdot 10^{-7} \textrm{ H/m}$ and the nuclear Curie constant $\lambda_N$ is given by   \begin{equation}  \label{eq:CurieConstant}  \frac{\lambda_N}{\mu_0} = N_A I (I+1)\frac{\left({\mu}_N g_N\right)^2}{3 k_B} \textrm{ [J K / mol T^2]}. (mol T$^2$)]}.  \end{equation}  where the nuclear magneton $\mu_N = \frac{h e}{4 \pi M_p c} = 5.051 10^{-27} \textrm{ J/T}$ is a factor of 1836.1 smaller than the Bohr magneton $\mu_B$. Note that in this expression, we are assuming that the zero field field splitting (ZFS) is negligible in comparison to that from the applied field $H$.