Abstract

Abstract BACKGROUND: The effect of the inlet n ‐pentane load (IL), empty bed residence time (EBRT) and mineral medium (MM) addition on spore emission and elimination capacity (EC) was evaluated using the fungus Fusarium solani in a vermiculite‐based biofilter. RESULTS: When the process was operated at an EBRT of 3.7 min and an IL of 100 g m $_{\rm {reactor}}^{-3}$ h −1 , the weekly addition of MM from 6.8 to 13.6 mL MM L $_{\rm {vermiculite}}^{-1}$ resulted in fluctuacting dynamics of ECs and spore emission. When varying the n ‐pentane IL from 25 to 875 g m $_{\rm {reactor}}^{-3}$ h −1 , a maximum EC of 110 g m $_{\rm {reactor}}^{-3}$ h −1 associated with a spore emission of 1.8 × 10 4 CFU m $_{\rm {air}}^{-3}$ was recorded. The critical inlet load for 90% n ‐pentane removal was 50 g m $_{\rm {reactor}}^{-3}$ h −1 with spore emission 4.5 × 10 3 CFU m $_{\rm {air}}^{-3}$ . Finally, when the EBRT was decreased from 3.7 to 2.1 min at a constant n ‐pentane IL of 50 g m $_{\rm {reactor}}^{-3}$ h −1 the EC decreased by 110%. CONCLUSIONS: The results show a poor performance of the n ‐pentane biofiltration system at high IL and low EBRT, which was further confirmed by the low final biomass concentrations in the biofilter (62 mg biomass g $_{\rm {vermiculite}}^{-1}$ ). Copyright © 2012 Society of Chemical Industry