Abstract
The biofiltration of n-hexane is studied to optimize determinants factors of hydrophobic VOC filtration efficiency. Four trickle-bed air biofilters (TBABs) were employed; two of which were supplied with nutrients buffered at a neutral pH, while another two at an acidic pH of 4 to induce and enhance fungal growth. The loading rate of n-hexane was kept constant in all TBABs at 13 g/m3/h. At each pH levels studied, the biomass of the TBABs was pre-acclimated using different ratios of n-hexane and methanol. The fungal biomass responsible for the degradation of n-hexane was then examined and quantified. Dichloran Rose Bengal Chloramphenicol agar was used for fungi quantification, and optical microscopy for classification. Effluent biomass was validated by measuring volatile suspended solids. Fungal counts resulting from n-hexane biodegradation were related to nitrate and carbon consumption. It was found that n-hexane elimination capacity closely followed biomass growth, and reached a steady-state at an optimum biomass density of roughly 3000 cfu/ml. Major shifts in fungal species were observed in all TBABs. Dominant fungal species grew slowly to become the most numerous, and were found to provide maximum elimination capacity, although TBABs pre-acclimated to higher methanol concentrations took less time to reach this steady-state. It was concluded, therefore, that steady and monitored growth of TBAB biomass is an essential factor in maximizing fungi’s ability to metabolize VOCs and that a new ecological biofiltration model may be the most effective at VOC purification. Keywords
Highlights
Utilization of volatile organic compounds (VOCs) has been, and continues to be, prevalent in industry
The information attained in this study is pertinent to industries in which VOC emissions are regulated
As industries seek biofiltration as a means of efficient VOC elimination, efficiency becomes a priority in this world of profit maximization
Summary
Utilization of volatile organic compounds (VOCs) has been, and continues to be, prevalent in industry. All indicate changes in biomass diversity with respect to time and changes to biofilter conditions It is these same changes and the possible correlations between microorganisms and biofiltration efficiency that this study sought to elucidate. The microbial fungi culture of four TBABs operating under different conditions to remove n-hexane was characterized and quantified. This study sought to understand the relative ecosystem established by a complex community of fungi in TBABs. In addition to attempting to characterize the overall fungal community and factors that may induce additional VOC removal efficiency, general fungal morphology was characterized at different stages of the filter ecosystem’s development
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