Effective charge state: Difference between revisions

The effective charge state of ions in a plasma ${\displaystyle Z_{eff}}$ is important to many physical processes.

${\displaystyle Z_{eff}={\frac {\sum _{i}n_{i}Z_{i}^{2}}{\sum _{i}n_{i}Z_{i}}}}$

where ${\displaystyle n_{i}}$ is ion density for species ${\displaystyle i}$ and ${\displaystyle Z_{i}}$ is the charge state of species ${\displaystyle i}$.

${\displaystyle \sum _{i}n_{i}Z_{i}=n_{e}}$ by quasi-neutrality, so

${\displaystyle Z_{eff}={\frac {\sum _{i}n_{i}Z_{i}^{2}}{n_{e}}}}$

${\displaystyle Z_{eff}}$ would be 1 for a plasma composed purely of hydrogen isotopes, but in practice is always higher due to impurities from plasma facing components. ${\displaystyle Z_{eff}=2}$ is a common baseline assumption for carbon-walled tokamaks,^[1][2] and some multi-device databases are restricted to cases with low-ish ${\displaystyle Z_{eff}}$^[3], making their scaling laws valid for ${\displaystyle Z_{eff}<3}$ and questionable for higher ${\displaystyle Z_{eff}}$. The 1999 ITER physics basis estimates ${\displaystyle Z_{eff}=1.8-1.9}$;^[4][5] higher than this will dilute the fuel too much.

References