The use of naturally generated volatile fatty acids for pesticide removal during the denitrification process

He, Xuan (Sarah)

January 2006

The effect of naturally produced volatile fatty acids (VFAs) on the removal of 2, 4-D from a wastewater during the denitrification process was studied in this thesis. The VFAs were generated from an anaerobic digester using soya flour solution as a synthetic feed. The digester was operated at an SRT and HRT of 10 days. The pH (4.8 ± 0.2) and temperature (32 ± 3 ℃) of the digester were not controlled. A mean VFA concentration of 3153 ± 801 mg/L was achieved with acid speciation results of acetic (51.4 %), propionic (27.5 %), n-butyric (19.6 %) and iso-valeric (1.4 %). The specific VFA production rate was 0.014 mg VFA/mg VSS/day. The extent of the digestion process converting the substrate from a particulate to soluble form was evaluated as the specific TOC solubilization rate (0.007 mg TOC/mg VSS/day), soluble COD production rate (0.022 mg SCOD/mg VSS/day) and percent VSS reduction (14 %). The low solubilization rate is possibly due to high feed solids (3.4%) which led to a heavily overloaded bioreactor. It also suggests that the particulate substrate was not entirely amenable to solubilization. The acclimation of 2, 4-D degrading bacteria was developed successfully in an SBR fed with sewage and 2, 4-D (30-100 mg/L) as carbon and energy sources. A mean MLSS of 3653 ± 547 mg/L and an SRT of 20 ± 9 days were observed during the research period. The settleability of the SBR sludge was excellent evidenced by a low sludge volume index (SVI) of 101 ± 50 mL/g and less than 5 mg/L of effluent suspended solids. The specific 2, 4-D degradation rate was 0.046 ± 0.018 mg/mg MLSS/day. However, the removal of 2, 4-D during 60 minutes of non-aerated phase was negligible while more than 90 % of the 2, 4-D was removed within 240 minutes of the aerated phase. The successful degradation of 2, 4-D is related to the length of the acclimation period, as the acclimation period increased, the specific biodegradation rate increased. A biosorption study using ultrasound pre-treatment of the SBR acclimated biomass suggested that less than 10 % of the removal of 2, 4-D was due to biosorption, while more than 90 % removal of the 2, 4-D was likely due to biodegradation. Denitrification batch tests (using SBR-acclimated biomass) demonstrated that the addition of a digester effluent rich in naturally-produced VFAs increased both the 2 specific denitrification rate and the 2, 4-D degradation efficiency, as compared to that using 2, 4-D as a sole carbon source. In particular, the specific denitrification rates increased from 0.0119 ± 0.0039 to 0.0192 ± 0.0079 to 0.024 ± 0.003 g NO₃-N/g VSS per day, when using 2, 4-D alone, 2, 4-D plus natural VFAs and natural VFAs alone as carbon sources. The percent 2, 4-D removal increased from 28.33 ± 11.88 using 2, 4-D alone as a carbon source to 54.17 ± 21.89 using 2, 4-D plus natural VFAs as carbon sources. The specific 2, 4-D degradation rate and 2, 4-D removal efficiency of unacclimated biomass were 2.0 to 2.5 times less than those of the acclimated biomass. Natural VFAs and synthetic VFAs were found to be identical in denitrification batch tests in terms of their use as a carbon source. The mean specific denitrification and VFA-C consumption rates as well as the mean specific 2, 4-D degradation rate derived from experiments using natural VFAs and 2, 4-D as carbon sources were close to the valuess from experiments using synthetic VFAs and 2, 4-D as carbon sources. Further exploration of 2, 4-D degradation behaviour with pulsed additions of NO₃-N did not find further significant 2, 4-D removal, although almost all of NO₃-N was used by the end of the experimental run due to endogenous carbon sources used for cell maintenance and growth. However, the higher the concentration of biomass used in the denitrification batch system, the larger the amount of 2, 4-D degraded and the faster the VFA-C and NO₃-N were consumed. Further research with respect to optimisation of the acid-phase anaerobic digestion process (e.g. to adjust SRT and HRT or to lower the solid content of synthetic feed) would improve the specific VFA production rate and the solubilization rate. More research on the SBR could be carried out to investigate its maximum 2, 4-D removal capability as well as the removal of other structurally related herbicides. Attempts could be made to stimulate the growth of denitrifiers in the SBR (e.g. to add certain amounts of NO₃-N according to proper C: N ratios or to increase the length of non-aerated time). More microbiological studies of 2, 4-D degrading bacteria may also be helpful to understand the combined SBR/denitrification and 2, 4-D degradation process. More theoretical aspects of modelling kinetics could be developed to apply the combined process in-situ at 2, 4-D contaminated sites.

naturally produced volatile fatty acids

denitrification process

Transformações na matéria orgânica nos sedimentos e águas eutrofizados da Represa Ibirité (Ibirité-Sarzedo, MG) tratados com nitrato de cálcio em microcosmos

Colzato, Marina

19 November 2010

Made available in DSpace on 2016-06-02T20:36:29Z (GMT). No. of bitstreams: 1 3420.pdf: 2614487 bytes, checksum: f5253a1d38ba330cdd10daa1e3e451b4 (MD5) Previous issue date: 2010-11-19 / Financiadora de Estudos e Projetos / Due to the growing concern with the environment and the welfare of future generations the search for the restoration of degraded areas and the reestablishment of equilibrium between the anthropogenic and natural environments are nowadays highlighted. The Ibirité Reservoir (Ibirité-Sarzedo, MG) is an example of water body impacted by the disorganized urbanization and strong industrial development in the metropolitan Belo Horizonte, MG, SE Brazil. The reservoir, built by the REGAP-Petrobras in the sixties to supply water to its industrial processes, is a eutrophic water body due to the continuous contribution of urban sewage (external loading) and the consequent internal loading of nutrients (mainly of phosphorus), the primary element responsible for the eutrophication process. Among the existing technologies for the treatment of eutrophic sediment focusing on the P immobilization is the artificial supply of nitrate as an electron acceptor to the stimulation of the natural denitrification process. In this stimulation process, the different geochemical forms of reduced iron are oxidized to iron (III) oxi-hidroxides that adsorbs the phosphorus present in the sediment pore water. In addition to that, the metallic sulfides and the organic matter are oxidized as well. This work aimed at the development of laboratory experiments in a bench scale (microcosms) in which sediments and water of the Ibirité reservoir were treated with nitrate addition in order to evaluate the organic matter transformations from caused this treatment. The results indicate that there was, in the treatment microcosms, an increase in the redox potential, an almost complete abatement of the acid volatile sulfide (AVS) of the sediments, and a significant reduction of available phosphorus in the water. The UVvis spectroscopy indicated differences in the spectral profiles between the control and treatment microcosms, but uniform trends along the experiment were not identified. The elemental analysis showed agreement with the results of AVS and nitrogen species in sediment pore water data, with the reduction of sulphur and nitrogen contents. / Diante da crescente preocupação com o meio ambiente e o bem estar das futuras gerações, destacam-se cada vez mais a busca pela recuperação das áreas degradadas e o restabelecimento do equilíbrio nas relações entre os meios natural e antrópico. A Represa Ibirité (Ibirité-Sarzedo, MG) é um exemplo de corpo de água impactado pela urbanização desorganizada e crescimento industrial da região metropolitana de Belo Horizonte, MG. A represa, construída pela REGAP-Petrobrás na década de 60 para suprimento de água em seus processos industriais, encontrase eutrofizada devido ao contínuo aporte de esgotos urbanos não tratados (carga externa) e à conseqüente carga interna de nutrientes, principalmente o fósforo, o principal responsável pelo processo de eutrofização. Dentre as tecnologias existentes para o tratamento de sedimentos eutrofizados, visando a imobilização do P, figura a adição de nitrato como um receptor de elétrons para o estímulo do processo natural de desnitrificação. Nesta estimulação, as diferentes formas geoquímicas de ferro reduzido são oxidadas a óxi-hidróxido de ferro (III) que adsorve o fósforo presente nas águas intersticiais, promovendo também, a oxidação dos sulfetos metálicos e a matéria orgânica presentes nos sedimentos. Neste trabalho o tratamento dos sedimentos e águas eutrofizados da Represa Ibirité foi avaliado em escala de bancada, utilizando microcosmos, onde se estudou a transformação da matéria orgânica presente nas águas de coluna, nos sedimentos e suas águas intersticiais. Os resultados indicam que houve, nos microcosmos-tratamento, um aumento do potencial redox do meio, um quase total abatimento do SVA dos sedimentos e uma redução do fósforo disponível nas águas em um nível bastante expressivo. As espectroscopias na região do UV-vis indicaram alterações nos perfis espectrais entre os microcosmos-controle e tratamento, sem, no entanto, identificar uma tendência uniforme ao longo dos períodos do experimento. A análise elementar foi concordante com os resultados de SVA e de espécies nitrogenadas nas águas intersticiais, pois mostram uma redução do teor de enxofre e de nitrogênio.

Química analítica

Química ambiental

Remediação

Sedimentos

Matéria orgânica

Espectroscopia de ultravioleta

Desnitrificação

Espectrocospia UV-vis

Remediation

Denitrification process

Organic matter

Sediments

UV-vis spectroscopy

CIENCIAS EXATAS E DA TERRA::QUIMICA