title H, He in STE
c from Ferland and Rees 1988
c this tests whether thermal processes go to STE
c
c commands controlling continuum =========
black body, t = 50000 STE
c
c commands for density & abundances =========
hden 10
init file="hheonly.ini"
c
c commands controlling geometry  =========
stop lyman optical depth -6
set dr -10
stop zone 1
c
c other commands for details     =========
iterate
c
c commands controlling output    =========
print heating
print populations h-like
print departure coef h-like
print departure coef he-like
save overview "limit_lte_hhe_ste.ovr"
save performance "limit_lte_hhe_ste.per"
save monitors "limit_lte_hhe_ste.asr" last
c
c commands giving the monitors    =========
monitor hydrogen 2 temperature 50000
monitor helium 3 temperature 50000
monitor h-like hydrogen depature coef, mean = 1
//
// >>chng 02 apr 24, increase error, H rec cool affected temp
// >>chng 09 oct 22, increase error, drift away from 1
monitor h-like helium depature coef, mean = 1 error 0.1
//
c limit_lte_hhe_ste.in
c class limit 
c ========================================
c 

This is the ultimate test of the behavior of the code in the
strict thermodynamic equilibrium limit. The temperature is not
held constant, so the resulting equilibrium temperature determines
whether cooling processes are treated properly in the detailed balance limit.
The equilibrium temperature should be exactly 5*104 K, and all
departure coefficients should equal unity. A small amount of
grains are included to check that the grain thermal balance is
handled properly in this limit. 

Checks:
-	Electron temperature exactly 5*104 K.
-	Departure coefficients unity.