this is for holding javascript data
Edwin E. Quashie edited At_low_velocity_our_results__.tex
almost 8 years ago
Commit id: 49a2871bc40da6b82a16822cc5e0a5ecc01ff927
deletions | additions
diff --git a/At_low_velocity_our_results__.tex b/At_low_velocity_our_results__.tex
index 99a70a8..c692ff4 100644
--- a/At_low_velocity_our_results__.tex
+++ b/At_low_velocity_our_results__.tex
...
We expect similar results for other transition metals, as described by Ref.~\cite{Markin_2008}.
Below $0.07~\mathrm{a.u.}$, the lack of experimental points precludes a direct comparison, but we find linear behavior at least down to $0.02~\mathrm{a.u.}$.
Below $0.02~\mathrm{a.u.}$ the direct real time integration becomes less efficient and the accuracy is compromised by the quality of the numerical time integrator and the number of steps necessary to complete a
calculation\cite{Schleife_2012}. calculation~\cite{Schleife_2012}.
One possible explanation is that bound effects break down the linear response (Lindhard) approximation that was useful to interpret the different regimes (and crossover) for velocities above $0.02~\mathrm{a.u.}$.
Probing this regime experimentally would be rather difficult, especially to disentangle it from nuclear stopping effects, but if this is confirmed it would be an unexpected new regime possibly related to bound effects.
In any case, the combination of experimental and theoretical results shows that the limit $v\to 0$ is intricate for metals as it is for insulators \cite{Artacho_2007, Lim_2015} where analogous band and gap threshold effects have been found.