Modeling atmospheric radon removal rate by naphthenic oil

Rocker, Austin Edwin

12 1900

No description available.

Radon

Naphthenic acids

Anoxic Biodegradation of Naphthenic Acid Using Nitrite as an Electron Acceptor

2014 October 1900

Extraction of bitumen from oil sands by surface mining and alkaline hot water process has generated large amount of oil sand process water (OSPW) which are contaminated by naphthenic acids (NAs). Due to the toxic and harmful nature of NAs, OSPW have been stored on-site in extremely large tailing ponds. With the understanding that the OSPW must be treated before their release into the natural water bodies and the need for reuse of the water, there is an urgent need in finding ways to treat these OSPWs effectively and economically. Numerous works on different treatment methods including photocatalysis, ozonation, adsorption, phytoremediation, simulated wetlands and bioremediation have been conducted and bioremediation has been proved as one of the most feasible ways among these methods. Research works on biodegradation of NAs, both aerobically and anoxically, have been conducted intensively in our research group in the past several years. Using surrogate NAs, specially trans-4-methyl-1-cyclohexane carboxylic acid (trans-4MCHCA), aerobic (Paslawski et al., 2009a,b,c, Huang et al., 2012; D’Souza et al., 2013) and anoxic (Gunawan et al., 2014) biodegradations of NA have been studied in batch, CSTR, biofilm system and circulating packed-bed bioreactor. Effects of naphthenic acid concentration, temperature, and naphthenic acid loading rate on the biodegradation process have been investigated. The results of the anoxic biodegradation of trans-4MCHCA in the presence of nitrate as an electron acceptor revealed that its performance was similar or better than the aerobic biodegradation. The results of that study also indicated the production of nitrite during the denitrification of nitrate and its subsequent consumption as part of biodegradation process. Given the importance of denitritation (nitrite reduction) as an essential step in anoxic biodegradation in the presence of nitrate, and the potential inhibitory effect of nitrite, the current research was conducted with the aim of investigating the performance of the anoxic biodegradation of trans-4MCHCA in the presence of nitrite as an electron acceptor, using batch, CSTR and biofilm reactors. The results of batch studies showed that nitrite at concentration up to 690 mg L-1 did not have a marked inhibitory effect but concentrations above 920 mg L-1 imposed a strong inhibitory effect. The optimum temperature was found to be in the range 24 C to 30°C. Continuous anoxic biodegradation of trans-4MCHCA with nitrite in CSTR achieved the maximum trans-4MCHCA biodegradation rate of 14.4 mg L-1 h-1 at a trans-4MCHCA loading rate of 22.9 mg L-1 h-1, which was about seven fold lower than the maximum trans-4MCHCA biodegradation rate observed with nitrate as an electron acceptor (105.4 mg L-1 h-1; Gunawan 2013). Both the trans-4MCHCA and nitrite degradation rates decreased with further increase of trans-4MCHCA loading rate. Using the experimental data the biokinetic coefficients Y (biomass yield), Ke (endogenous rate constant), μm (maximum specific growth rate) and Ks (saturation constant) were determined as 0.3 mg cell mg substrate-1, ~0 h-1, 0.4 h-1 and 20.9 mg substrate L-1, respectively. Similar pattern was observed in the biofilm system whereby the maximum trans-4MCHCA biodegradation rate was 82.2 mg L-1 h-1 at a trans-4MCHCA loading rate of 171.8 mg L-1 h-1, was about five folder lower than the maximum trans-4MCHCA biodegradation rate observed when nitrate was used as an electron acceptor (435.8 mg L-1 h-1; Gunawan 2013). The findings of current study suggested that the anoxic NA biodegradation in the presence of nitrite occurred at rates which were lower than those observed in the presence of nitrate, as well as those obtained under aerobic conditions with oxygen as the electron acceptor.

Naphthenic Acid

Nitrite

Biodegradation

Uso da Microcromatografia Gasosa no Estudo da Evolução do Gás CO2 no Processo de Destilação Laboratorial de Petróleo

LIMA, T. A.

20 February 2017

Made available in DSpace on 2018-08-01T21:58:47Z (GMT). No. of bitstreams: 1 tese_10597_Dissertação Tamires FINAL 08042017.pdf: 3045708 bytes, checksum: 346790de110160baf3a5382b4013c028 (MD5) Previous issue date: 2017-02-20 / O petróleo ainda continua sendo a maior fonte de energia não renovável do planeta. No seu estado bruto tem pouca utilidade. No entanto, seus derivados apresentam alto valor econômico. Nas etapas de processamento primário do petróleo alguns compostos de ocorrência natural são indesejáveis, como os ácidos naftênicos, resinas, asfaltenos, compostos sulfurados e metálicos. O poder corrosivo dos ácidos naftênicos preocupa as indústrias petrolíferas devido ao prejuízo causado nas tubulações e refinarias. Estudos recentes indicam que uma parcela desses ácidos quando submetidos a elevadas temperaturas (>280°C) pode sofrer reações de descarboxilação e degradação térmica, originando dióxido de carbono (CO2) e ácidos de cadeias menores como produtos de degradação. Os ácidos de cadeias menores juntamente com os ácidos naftênicos que se mantiveram preservados são corrosivos e o CO2 ao entrar em contato com água forma o ácido carbônico (H2CO3), podendo contribuir nas taxas de corrosão nos equipamentos do refino. Assim, o presente trabalho consistiu no desenvolvimento de uma metodologia para quantificação online do CO2 liberado no processo de destilação de petróleo. A metodologia desenvolvida foi baseada na técnica de microcromatografia gasosa. Os dados quantitativos de concentração de CO2 gerados pela microcromatografia foram relacionados com os valores de temperaturas de destilação, obtendo-se assim uma variação na concentração de CO2 de acordo com a temperatura de destilação do óleo. Com os resultados obtidos observou-se que para todos os petróleos destilados houve uma tendência na formação do gás CO2 partir de temperaturas superiores a 200°C. Na tentativa de elucidar a possível origem deste gás, supôs um mecanismo de descarboxilação para tais ácidos

Carbon dioxide

Naphthenic acids

Studies with naphthenic acids in the bush bean, phaseolus vulgaris L.

Severson, John George

January 1971

The overall objective of these experiments was to augment our understanding of how naphthenic acids stimulate metabolism and growth of bean plants. Three separate studies were carried out with bush bean plants (Phaseolus vulgaris L. cultivar Top Crop) to determine: 1) the effect of potassium naphthenates (KNap) on the uptake, distribution, and incorporation of phosphorus-32, 2) the metabolism of the individual naphthenic acid, potassium cyclohexanecarboxylate (KCHC), in leaves and roots, and 3) the effect of KNap and KCHC on the uptake and metabolism of glucose by excised root tips. 1) Fourteen-day-old plants growing in a phosphate-free (-P) or a complete (+P) nutrient solution were sprayed to drip with a 0.5% solution of KNap. Twenty-four hours after spraying, the roots of both control and treated plants were exposed for 2 hours to a nutrient solution containing ³²P. Following the exposure to ³²P, the plants were returned to their original nutrient solutions. Control and treated plants were withdrawn 4, 8, 12, and 24 hours after exposure to ³²P, and were separated into leaf blades, stems, and roots. Acid soluble, acid insoluble, and total ³²P activity, or total phosphorus were determined at each sampling time. KNap treatment increased by 7 to 9% the intake of ³²P by plants grown in the -P or +P nutrient solution. The increases, however, lacked statistical significance at the 0.05 level. The rate at which ³²P was translocated out of the roots of plants grown in the -P nutrient only was increased significantly by treatment, in spite of the fact that at the 24 hour sampling time 84% of the total ³²P label remained in root tissues. At the same sampling time 32% of the total ³²P label was found in the roots of plants grown in the +P nutrient. While KNap treatment significantly increased ³²P activity in stems of -P grown plants over the sampling period, activity in stems of control and treated plants grown in the +P nutrient was similar. Naphthenate treatment increased the rate of incorporation of ³²P into both the acid soluble (sugar phosphates, nucleotides, phospholipids) and acid insoluble (nucleic acids, phosphoproteins) fractions of leaves of plants grown in the +P nutrient solution. Acid soluble ³²P activity declined in all root tissues over the sampling period as acid soluble ³²P-containing compounds, primarily orthophosphate, were translocated acropetally. The percentage acid insoluble ³²P activity in the roots of KNap-treated plants was significantly greater than that found in the roots of control plants at the 24 hour sampling time. Naphthenate treatment did not affect the amount of total P (³¹P + ³²P) in the two P fractions of the three plant organs. The augmented incorporation of ³²P into the acid soluble and acid insoluble fractions is further evidence of the KNap-stimulated P metabolism reported by other workers. 2) KCHC-7-¹⁴C administered to leaf disks in the light or to roots of intact seedlings in the dark was rapidly converted to a mixture of two conjugated metabolites: the glucose ester and the aspartic acid amide. The root-feeding experiment indicated that following their synthesis in root tissues both conjugates were translocated acropetally. The results of amino acid analyses of the acid hydrolysates of several unidentified metabolites strongly suggest that KCHC-7-¹⁴C was also conjugated with a low molecular weight polypeptide. 3) Three sets of root tips cut from 7-day-old seedlings were incubated in a medium containing ¹⁴C glucose for 3 hours. Two of the three sets were pretreated in a solution of KCHC or KNap for 6 hours. Each naphthenate treatment significantly increased ¹⁴C activity in the ethanol-soluble (amino acids, glucose, etc.), ethanol-insoluble (polysaccharides, protein, etc.), and respired CO₂ fractions. The individual naphthenic acid, KCHC, had the greater effect on the uptake and metabolism of labelled glucose. Results also indicated that not only were the uptake of glucose and CO₂ production increased significantly by each treatment, but also amino acids containing the glucose carbon passed more quickly through soluble amino acid pools in root tissues, and were more rapidly fixed into protein. In light of the finding that naphthenate conjugates and not the free acid were detected in the tissue, it may be that the conjugates were associated in a causal way with the stimulated uptake and metabolism of labelled glucose. / Science, Faculty of / Botany, Department of / Graduate

Naphthenic acids

Common bean

Ozonation and biodegradation of oil sands process water

Wang, Nan

Unknown Date

No description available.

ozonation

biodegradation

naphthenic acid

toxicity

Understanding the Role of Caustic Addition in Oil Sands Processing

Zhu, Qian

Unknown Date

No description available.

Bitumen Extraction

Caustic

Naphthenic Acids

Ozonation and biodegradation of oil sands process water

Wang, Nan

06 1900

To ensure oil sands process water (OSPW) is suitable for discharge into the environment, advanced water treatment technologies are required. In this study, integrated ozonation-biodegradation was investigated as a potential treatment option for OSPW. The treatment efficiency was evaluated in terms of naphthenic acid (NA) degradation, chemical oxygen demand (COD), carbonaceous Biological oxygen demand (CBOD), and acute toxicity reduction. Degradation of NAs of more than 99% was achieved using a semi-batch ozonation system at a utilized ozone dose of 80 mg/L combined with subsequent biodegradation. The results also show that ozone decreased the amount of COD while increasing the biodegradability of COD. It was noted that the carbon number and number of NA rings influenced the level of NA oxidation. With a utilized ozone dose of approximately 100 mg/L, the ozonated and biodegraded treated OSPW showed no toxic effect towards bacterium Vibrio fischeri. The results of this study indicate that integrated ozonation-biodegradation is a promising treatment technology for OSPW. / Environmental Engineering

ozonation

biodegradation

naphthenic acid

toxicity

Kinetics of liquid-solid reactions in naphthenic acid conversion and kraft pulping

Yang, Ling

11 1900

Two liquid-solid reactions, in which the morphology of the solid changes as the reactions proceeds, were examined. One is the NA conversion in oil by decarboxylation on metal oxides and carbonates, and the other is the Kraft pulping in which lignin removal by delignification reaction. In the study of the NA conversion, CaO was chosen as the catalyst for the kinetic study from the tested catalysts based on NA conversion. Two reaction mixtures, carrier oil plus commercial naphthenic acids and heavy vacuum gas oil (HVGO) from Athabasca bitumen, were applied in the kinetic study. The influence of TAN, temperature, and catalyst loading on the NA conversion and decarboxylation were studied systematically. The results showed that the removal rate of TAN and the decarboxylation of NA were both independent of the concentration of NA over the range studied, and significantly dependent on reaction temperature. The data from analyzing the spent catalyst demonstrated that calcium naphthenate was an intermediate of the decarboxylation reaction of NA, and the decomposition of calcium naphthenate was a rate-determining step. In the study on the delignification of the Kraft pulping, a new mechanism was proposed for the heterogeneous delignification reaction during the Kraft pulping process. In particular, the chemical reaction mechanism took into account the heterogeneous nature of Kraft pulping. Lignin reacted in parallel with sodium hydroxide and sodium sulfide. The mechanism consists of three key kinetic steps: (1) adsorption of hydroxide and hydrosulfide ions on lignin; (2) surface reaction on the solid surface to produce degraded lignin products; and (3) desorption of degradation products from the solid surface. The most important step for the delignification process is the surface reaction, rather than the reactions occurring in the liquid phase. A kinetic model has, thus, been developed based on the proposed mechanism. The derived kinetic model showed that the mechanism could be employed to predict the pulping behavior under a variety of conditions with good accuracy. / Chemical Engineering

kinetics

naphthenic acid conversion

kraft pulping

Sorption of Naphthenic Acids using β-Cyclodextrin-based Polyurethanes

Mohamed, Mohamed Hamid

19 April 2011

<p>In general, the research focuses on sequestration of naphthenic acids (NAs) from simulated oil sands process water (OSPW) conditions using engineered copolymers known as &beta;-cyclodextrin-based polyurethanes. The thesis research is divided into two main parts; <i>i)</i> synthesis and characterization of &beta;-cyclodextrin-based polyurethanes, and <i>ii)</i> sorption studies of the copolymer materials with NAs from aqueous solutions.</p> <o>In the first part, &beta;-cyclodextrin (&beta;-CD) was crosslinked with five types of linker molecules, respectively, under various synthetic conditions. The various diisocyanates investigated as linkers include the following: 1,6-hexamethylene diisocyanate (HDI), 4,4'-dicyclohexylmethane diisocyanate (CDI), 4,4'-diphenylmethane diisocyanate (MDI), 1,4-phenylene diisocyanate (PDI) and 1,5-naphthalene diisocyanate (NDI). The polyurethanes (PUs) were systematically designed at different mole ratios of monomers by maintaining &beta;-CD and varying the relative mole ratio of diisocyanate monomer from unity to greater values. Diffuse Reflectance Infrared Fourier Transform spectroscopy (DRIFTS), solid state ¹³C CP-MAS NMR, solution state ¹H/¹³C NMR spectroscopy, thermogravimetric analysis (TGA), elemental analysis (CHN), nitrogen porosimetry, and a dye-based (p-nitrophenol; PNP, and phenolphthalein; phth) sorption method were used to characterize the copolymer materials. In general, the &beta;-CD PUs were insoluble in water except for &beta;-CD crosslinked with HDI at the 1:1 mole ratio which was moderately water soluble. All techniques show complementary results about the structural and compositional characterization, particularly for the estimation of the ratios between the co-monomers. The optimal preparation of copolymer materials for sorption-based applications occurs for &beta;-CD/linker monomer mole ratios from 1:1 to 1:3. There is a maximum limit of the crosslinking density which is ~ 1:7 (&beta;-CD:linker) according to the steric effects of the substituents in the annular region of &beta;-CD. Also, the copolymers were generally found to be mesoporous with relatively low surface area (BET; ~10¹ m²/g) and they appear to exhibit swelling in aqueous solution due to hydration as observed from the estimation of the dye-based surface areas using PNP. The surface accessibilities of the &beta;-CD inclusion sites ranged between 1-100%, as evidenced by the decolourization of phenolphthalein (phth) due to the formation of 1:1 &beta;-CD/phth inclusion complexes.</p> <p>In the second part, the inclusion of NAs and its surrogates with three well known types of cyclodextrin (&alpha;-, &beta;-, and &gamma;-CD) was confirmed using negative ion mode electrospray ionization (ESI). The CDs were found to form well-defined 1:1 inclusion complexes. The binding constant (K2) of NAs and its surrogates inclusion with &beta;-CD was determined indirectly using the spectral displacement technique and were found to be 10³-10⁴ M^-1 (surrogates) and ~ 10⁴ M^-1 (NAs), respectively. Furthermore, the binding constants were found to increase with an increase of the lipophilic surface area (LSA) of the surrogates. The sorption results of NAs with three different types of &beta;-CD materials (i.e. &beta;-CD PU, &beta;-CD crosslinked with epichlorohydrin (EP) and a silica-based mesoporous material containing &beta;-CD), showed &beta;-CD PU had a greater affinity. The sorption capacity (~ 0 - 75.5 mg NAs/g copolymer) and binding affinity (~10³ - 10⁴ M^-1) of &beta;-CD PUs varied due to the nature of linker monomer and the mole ratio of the co-monomers. Aromatic-based copolymers showed high sorption binding affinity while aliphatic-based copolymers showed a relatively high sorption capacity at the co-monomer ratio. Finally, Syncrude-Derived NAs showed fluorescent characteristics which contradict the classic definition of NAs. Further studies using UV-Vis and fluorescence emission spectroscopy showed potential development of an analytical method that can be used to quantify NAs in OSPW for <i>in-situ</i> field applications.

sorption

complexation

naphthenic acids

cylclodextrin

polymer

isotherms

A laboratory evaluation of the sorption of oil sands naphthenic acids on soils

Janfada, Arash

02 January 2008

The adsorption characteristics of an oil sands tailings water (OSTW) mixture of naphthenic acids were determined using a batch partitioning method for two soils from the Alberta oil sands region. The soils were mineral peat mixtures produced during salvage operations, with Soil 1 having a higher organic carbon fraction (foc) than Soil 2. Naphthenic acids are a significant toxic byproduct of bitumen extraction, and are acutely toxic to aquatic organisms. The sorption of naphthenic acids as affected by a high ionic strength solution was examined using a synthetic groundwater (SGW) mixture.<p>The adsorption isotherms were found to be linear in all cases. All tests were conducted at 4oC, and at a pH of 8.0 ± 0.4, reflective of the conditions in a tailings settling facility near Fort McMurray, AB. The adsorption characteristics of the naphthenic acids in the SGW solution were compared to that of the mixture in Milli-Q water for the two soils. In the presence of SGW, the adsorption coefficient (Kd) for the mixture of naphthenic acids on Soil 1 was an order of magnitude higher than that observed with the same soil and the Milli-Q water mixture, increasing from 1.9 ± 0.2 mL/g to 17.8 ± 1.5 mL/g. The adsorption coefficient for the mixture of naphthenic acids on Soil 2 was also observably higher in the SGW mixture, increasing from 1.3 ± 0.15 mL/g to 3.7 ± 0.2 mL/g. In order to determine whether preferential sorption is exhibited by a particular species within the mixture, the relative fractional abundance of the individual naphthenic acids was plotted as a 3-dimensional histogram for carbon numbers 5 to 37. It was found that for all Z families (where Z is a measure of the number of carbon ring structures), naphthenic acids within the middle range of carbon numbers showed preferential sorption. A two sample t-test confirmed that the naphthenic acids in the carbon number groupings 15 to 24 and 25 to 37 sorbed significantly in the SGW mixture when compared to those in the carbon number grouping of 5 to 14. It was concluded that select constituents of oil sands naphthenic acids mixtures sorb strongly to soil under conditions of elevated salinity and therefore adsorption could be an important attenuating mechanism in groundwater transport. Furthermore, preferential sorption of the individual naphthenic acids is important with respect to toxicity since lower molecular weight naphthenic acids are believed to have a more pronounced toxic effect. Overall, the measured adsorption coefficients indicate that there can be significant sorption of OSTW derived naphthenic acids to soils.