The dynamics of aquatic systems (e.g. estuarine systems) are known to facilitate the
formation of particle aggregates. These nutrient-rich particulate matter provide suitable
substrate for bacteria colonization. Although bacteria-aggregate association is known to
result in the degradation of particulate organic matter (POM) in aquatic systems, it has
never been attributed to the production of methyl iodide (CH3I) (an environmentally
important biogas that has the potential to impact on atmospheric chemistry). From
literature, there are evidences which suggest that, certain bacteria (methylotrophs) are
capable of oxidizing methyl halides including CH3I. Therefore this study investigates
microbial production and removal of CH3I in estuarine water through their association with
aggregates and assesses the effect of physicochemical variables on bacterial-mediated
production and removal of CH3I. From the study, bacteria-aggregate processes were found
to elevate the concentration of CH3I between 15-22% of the total observed CH3I
concentration over the study period. Aggregate-attached bacteria which were estimated to
represent about 17% of the total bacteria population were responsible for about 37% of the
overall bacterial activity. To investigate bacterial-mediated removal of CH3I in estuarine
systems, a reliable and reproducible method through adaptations and modifications of
existing methods was developed. This method involved the use of [14C] radiolabelled CH3I
to estimate bacterial utilization of CH3I. The application of the method confirmed the
removal of CH3I by methylotrophs in estuarine water with the total recorded amount in
bacterial cells and oxidized C02 ranging between 9.3 - 24.5% (depending on the amount
of the added substrate). However, this could only represent the potential microbial CH3I
removal in the natural aquatic environment. An investigation into spatial and temporal
trends in bacterial-mediated removal of CH3I in the Tamar estuary revealed no significant
spatial variation but rather a strong seasonality in methylotrophic bacterial CH3I removal.
Spatial trends in CH3I removal was found to be mostly influenced by temperature, bacterial
abundance and dissolved oxygen concentration whilst the seasonality in the estuary was
influenced by temperature, bacterial abundance, suspended particulate matter (SPM) and
CH3I concentration. Temperature was identified to be the single most influential
physicochemical variable on both spatial and seasonal variation in bacterial CH3I removal
in the Tamar estuary. CH3I concentration along the Tamar estuary was also investigated
and using this data the total water to air flux of CH3I over the estuary was estimated to be
0.31 x 10³ g yˉ¹. From this study, it was apparent that bacteria activity in estuarine systems
is potentially an important source of CH3I in the aquatic environment when associated with
aggregates or as sink of CH3I through methylotrophic activity in estuaries.
Date of Award | 2007 |
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Original language | English |
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Awarding Institution | |
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MICROBIALLY-MEDIATED METHYL IODIDE CYCLING IN A PARTICLE-RICH ESTUARY
ASARE, N. K. (Author). 2007
Student thesis: PhD