FORMULATION OF NON-STEADY-STATE DUST FORMATION PROCESS IN ASTROPHYSICAL ENVIRONMENTS

The non-steady-state formation of small clusters and the growth of grains accompanied by chemical reactions are formulated under the consideration that the collision of key gas species (key molecule) controls the kinetics of dust formation process. The formula allows us to evaluate the size distribution and condensation efficiency of dust formed in astrophysical environments. We apply the formulation to the formation of C and MgSiO3 grains in the ejecta of supernovae, as an example, to investigate how the non-steady effect influences the formation process, condensation efficiency f(con,infinity), and average radius a(ave,infinity) of newly formed grains in comparison with the results calculated with the steady-state nucleation rate. We show that the steady-state nucleation rate is a good approximation if the collision timescale of key molecule tau(coll) is much smaller than the timescale tau(sat) with which the supersaturation ratio increases; otherwise the effect of the non-steady state becomes remarkable, leading to a lower f(con,infinity) and a larger a(ave,infinity). Examining the results of calculations, we reveal that the steady-state nucleation rate is applicable if the cooling gas satisfies Lambda = tau(sat)/tau(coll) greater than or similar to 30 during the formation of dust, and find that f(con,infinity) and a(ave,infinity) are uniquely determined by Lambda(on) at the onset time t(on) of dust formation. The approximation formulae for f(con,infinity) and a(ave,infinity) as a function of Lambda(on) could be useful in estimating the mass and typical size of newly formed grains from observed or model-predicted physical properties not only in supernova ejecta but also in mass-loss winds from evolved stars.