Diode laser absorption at 772.38 nm is used to measure the time resolved density of Ar* (3P2) metastable atoms in a capacitively coupled radio-frequency (RF) discharge running in an argon/acetylene mixture at 0.1 mbar. The RF power is pulsed at 100 Hz and the density of Ar* (3P2) atoms in the 5 ms ON time and in the afterglow is recorded. Different plasma conditions, namely (1) pure argon, (2) argon +7% acetylene before powder formation, (3) argon +7% acetylene after dust particles have been formed and (4) argon with dust particles remaining in the plasma volume but without acetylene, are studied. The measured steady-state Ar* (3P2) density in the middle of the reactor is always about 10 times larger in the dusty argon plasma than in the pure argon discharge. This is mainly a consequence of the enhancement of electron temperature after dust formation. Both steady-state densities and decay times in the afterglow indicate that the degree of dissociation of C2H2 in the plasma volume can be as high as 99%. It is shown that under our plasma conditions, the loss of Ar* (3P2) atoms on the surface of dust particles is negligible compared to their loss by diffusion to the electrodes.