deletions | additions       diff --git a/In_order_to_compare.tex b/In_order_to_compare.tex  index 04b76c1..abc1154 100644  --- a/In_order_to_compare.tex  +++ b/In_order_to_compare.tex 
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energy of the surface velocity field, $E_{\mathrm g}/E_{\rm s}$   (Eq.~\ref{ratio}),   assuming $\varv_{\rm s} = 10\kms$, in the HR diagram.  Fig.~\ref{grwplot} Fig.~\ref{fig:grwplot}  shows two different iso-contours of this ratio; the stars of the LMC sample shown in Fig.~\ref{microlmc} Fig.~\ref{fig:microlmc}  are over plotted. Notably, all but one of the LMC stars of Fig.~\ref{grwplot} Fig.~\ref{fig:grwplot}  with $\microt > 10\kms$ are found in that part of the HR diagram where it is energetically  possible that the FeCZ-induced gravity waves trigger a significant  surface velocity field ($\varv_{\rm s} > 10\kms$).   Thus, a physical connection of the FeCZ   with the observed microturbulent  velocities appears energetically possible. Moreover, that the iso-contour line of  $E_{\mathrm g}/E_{\rm s} = 1$ in Fig.~\ref{grwplot} Fig.~\ref{fig:grwplot}  almost perfectly divides the observed sample in stars with significant ($\microt > 10\kms$) and insignificant  ($\microt < 10\kms$) microturbulence is a further   indication of such a physical connection.