Your search keyword '"Fengmao Guo"' showing total 7 results

1. Size and XAD fractionations of trihalomethane precursors from soils

Author

Richard S. Breuer, Alex T. Chow, Fengmao Guo, and Suduan Gao

Subjects

Environmental Engineering, Health, Toxicology and Mutagenesis, complex mixtures, California, Water Purification, Electrolytes, Water Supply, Dissolved organic carbon, Soil Pollutants, Environmental Chemistry, Organic matter, Leaching (agriculture), chemistry.chemical_classification, Total organic carbon, Soil organic matter, Public Health, Environmental and Occupational Health, Environmental engineering, General Medicine, General Chemistry, Soil carbon, Pollution, Carbon, Resins, Synthetic, Solubility, chemistry, Loam, Environmental chemistry, Soil water, Trihalomethanes

Abstract

Soil organic matter is an important source of allochthonous dissolved organic matter inputs to the Sacramento-San Joaquin Delta waterways, which is a drinking water source for 22 million people in California, USA. Knowledge of trihalomethane (THM) formation potential of soil-derived organic carbon is important for developing effective strategies for organic carbon removal in drinking water treatment. In this study, soil organic carbon was extracted with electrolytes (deionized H2O and Na- or Ca-based electrolytes) of electrical conductivity bracketing those found in Delta leaching and runoff conditions. The extracts were physically and chemically separated into different fractions: colloidal organic carbon (0.45-0.1 microm), fine colloidal organic carbon (0.1-0.025 microm), and dissolved organic carbon (DOC) (

Published

2006

2. Trihalomethane Reactivity of Water- and Sodium Hydroxide-Extractable Organic Carbon Fractions from Peat Soils

Author

Alex T. Chow, Suduan Gao, Fengmao Guo, and Richard S. Breuer

Subjects

Environmental Engineering, Inorganic chemistry, chemistry.chemical_element, Management, Monitoring, Policy and Law, complex mixtures, Soil, chemistry.chemical_compound, Sodium Hydroxide, Humic acid, Organic matter, Organic Chemicals, Waste Management and Disposal, Water Science and Technology, chemistry.chemical_classification, Total organic carbon, Soil carbon, Pollution, Carbon, Trihalomethane, chemistry, Sodium hydroxide, Environmental chemistry, Soil water, Spectrophotometry, Ultraviolet, Trihalomethanes

Abstract

Certain organic carbon moieties in drinking source waters of the Sacramento-San Joaquin Delta can react with chlorine during disinfection to form potentially carcinogenic and mutagenic trihalomethanes. The properties of reactive organic carbon in Delta waters, particularly those of soil origin, have been poorly understood. This study attempts to characterize trihalomethane reactivity of soil organic carbon from three representative Delta peat soils. Soil organic carbon was extracted from all three soils with either deionized H2O or 0.1 M NaOH and sequentially separated into humic acids, fulvic acids, and nonhumic substances for quantitation of trihalomethane formation potential. Water-extractable organic carbon represented only 0.4 to 0.7% of total soil organic carbon, whereas NaOH extracted 38 to 51% of total soil organic carbon. The sizes and specific trihalomethane formation potential (STHMFP) of individual organic carbon fractions differed with extractants. Fulvic acids were the largest fraction in H2O-extractable organic carbon, whereas humic acids were the largest fraction in NaOH-extractable organic carbon. Among the fractions derived from H2O-extractable carbon, fulvic acids had the greatest specific ultraviolet absorbance and STHMFP and had the majority of reactive organic carbon. Among the fractions from NaOH-extractable organic carbon, humic acids and fulvic acids had similar STHMFP and, thus, were equally reactive. Humic acids were associated with the majority of trihalomethane reactivity of NaOH-extractable organic carbon. The nonhumic substances were less reactive than either humic acids or fulvic acids regardless of extractants. Specific ultraviolet absorbance was not a good predictor of trihalomethane reactivity of organic carbon fractions separated from the soils.

Published

2006

3. Quantifying the Available Soil Phosphorus Pool with the Acid Ammonium Oxalate Method

Author

Fengmao Guo and Russell Yost

Subjects

Phosphorus, Soil Science, Mineralogy, Soil chemistry, chemistry.chemical_element, Ammonium oxalate, Oxalate, chemistry.chemical_compound, chemistry, Environmental chemistry, Soil water, Qualitative inorganic analysis, Soil fertility, Calcareous

Abstract

Measurement of the available soil P pool is required for making P fertilization recommendations. Extractants capable of estimating this P pool are needed. The objective of this study was to explore the utility of the acid ammonium oxalate method for estimating available soil P pools in diverse soils. Oxalate extraction in the dark dissolves mainly active noncrystalline Fe and Al in the soil. Oxalate extractable P (P ox ) has rarely been investigated for predicting the available P pool in highly weathered soils, where Fe and Al oxides are usually abundant. We estimated P ox in five highly weathered soils and three slightly weathered soils amended with varying amounts of P. The size of the available P pool in each soil was also estimated by a modified Hedley sequential extraction and verified in a 14-crop exhaustive greenhouse experiment. Results indicated that P ox in all soils appeared to be largely plant-available. P ox was found unsuitable for quantifying the available P pool in the calcareous, slightly weathered soils. Carbonates raised the pH of the oxalate solution and reduced the concentration of the oxalate anion to differing degrees, thus making this method unreliable for quantifying available P pools in calcareous soils. In highly weathered soils, the relationship between the quantity of available P and P ox was described by a linear equation, Y = 294.7 + 1.05 X (r 2 = 0.81), where Y is estimated available P in mg P kg ', and X is P ox in mg P kg 1 . The P ox was a good predictor of the available P pool in the highly weathered soils that were measured by the Hedley procedure and a multicrop exhaustion experiment.

Published

1999

4. Reactions of copper sulfate with wetland‐taro soils in Hawaii

Author

Russell Yost, Fengmao Guo, Guoqing Zhang, Nguyen V. Hue, and Susan C. Miyasaka

Subjects

geography, geography.geographical_feature_category, biology, Soil Science, Mineralogy, chemistry.chemical_element, Sorption, Wetland, Pesticide, biology.organism_classification, Copper, chemistry, Soil pH, Environmental chemistry, Soil water, Agronomy and Crop Science, Pomacea canaliculata, Incubation

Abstract

The environmental impact of copper sulfate (CuSO4#lb5H2O) must be evaluated before the chemical can be registered as a pesticide to control the apple snail (Pomacea canaliculata) in Hawaii's wetlands. To help achieve this goal, we investigated the sorption‐desorption reactions of CuSO4#lb5H2O with six wetland‐taro soils (Tropaquepts) of Hawaii. Our results indicated that: (i) copper (Cu) was sorbed rapidly: 98.0–99.9% of the added Cu was removed from solution within one hour when the loading rate was less than or equal to 300 mg Cu kg‐1 [initial Cu concentration = 30.0 mg Cu L‐1 or 12 kg (ha‐cm)‐1 as CuSO4#lb5H2O which is 10 times the maximum recommended rate of pesticide applications, (ii) Cu sorption increased as soil pH increased from 5.0 to 8.0, and (iii) sorption capacity varied from 210 mg Cu kg‐1 in a Tropaquept from Kauai Island to 500 mg Cu kg‐1 in another Tropaquept from Maui Island, after seven days of incubation at soil‐solution pH 6.0 and total solution Cu concentration of 0.10 mg Cu...

Published

1997

5. Trihalomethane formation potential of filter isolates of electrolyte-extractable soil organic carbon

Author

Fengmao Guo, Richard S. Breuer, Suduan Gao, and Alex T. Chow

Subjects

Environmental Engineering, Chemistry, Organic, chemistry.chemical_element, Management, Monitoring, Policy and Law, complex mixtures, California, chemistry.chemical_compound, Electrolytes, Chlorine, Soil Pollutants, Organic matter, Organic Chemicals, Waste Management and Disposal, Water Science and Technology, chemistry.chemical_classification, Total organic carbon, Environmental engineering, Water, Soil carbon, Pollution, Leaching model, Carbon, Trihalomethane, chemistry, Environmental chemistry, Soil water, Water treatment, Filtration, Trihalomethanes

Abstract

Certain organic C moieties of soil origin in drinking source waters of Sacramento-San Joaquin Delta (Delta) can react with chlorine to form trihalomethanes (THMs) during the disinfection process. Isolation and characterization of them and quantitation of their THM formation potential (THMFP) is necessary for developing effective strategies to reduce their influxes in Delta waters and for removing them during drinking water treatment. In this study, organic C from two Delta soils was extracted using deionized H(2)O and four Na- or Ca-based electrolytes of varying electrical conductivity values. Extracts were filtered into particulate, colloidal, fine colloidal, and soluble organic C for quantitation and THMFP determination. Results suggested that1.5% of soil organic C was electrolyte-extractable. The soluble organic C fraction from both soils dominated in quantity and THMFP. Electrolyte effects were cation dependent. Sodium-based electrolytes at either conductivity level did not significantly decrease extractable organic C (EOC) or THMFP compared with deionized H(2)O. In contrast, Ca-based electrolytes reduced EOC and THMFP by50% even at 1 dS m(-1). Further increase in Ca concentration did not significantly decrease EOC or THMFP. Most reduction in EOC and THMFP by Ca-based electrolytes occurred with the fractions other than the soluble organic C. Results suggested that under natural soil leaching and runoff conditions, the majority of THMFP is associated with organic C of0.025 mum in diameter. Further molecular characterization of the fractions with high THMFP may help understand the nature of chlorine-reactive organic C from Delta soils.

Published

2005

6. Filter pore size selection for characterizing dissolved organic carbon and trihalomethane precursors from soils

Author

Alex T. Chow, Randy A. Dahlgren, Fengmao Guo, Suduan Gao, and Richard S. Breuer

Subjects

Environmental Engineering, Mineralogy, Portable water purification, Water Purification, chemistry.chemical_compound, Soil, Dissolved organic carbon, Organic matter, Turbidity, Waste Management and Disposal, Water Science and Technology, Civil and Structural Engineering, Total organic carbon, chemistry.chemical_classification, Ecological Modeling, Soil organic matter, Water, Pollution, Carbon, Ion Exchange, Trihalomethane, chemistry, Environmental chemistry, Soil water, Salts, Porosity, Filtration, Water Pollutants, Chemical, Trihalomethanes

Abstract

Filters with a pore size of 0.45 microm have been arbitrarily used for isolating dissolved organic carbon (DOC) in natural waters. This operationally defined DOC fraction often contains heterogeneous organic carbon compounds that may lead to inconsistent results when evaluating trihalomethane formation potential (THMFP). A finer pore size filter provides more homogeneous DOC properties and enables a better characterization of organic matter. In this study, we examined the effects of filter pore size (1.2, 0.45, 0.1 and 0.025 microm) on characterizing total organic carbon, ultra-violet absorbance at 254 nm (UV(254)) and THMFP of water extracts from a mineral and organic soil in the Sacramento-San Joaquin Delta, California. Results showed that the majority of water extractable organic carbon (WEOC) from these soils was smaller than 0.025 microm, 85% and 57% in organic and mineral soils, respectively. A high proportion of colloidal organic carbon (COC) in mineral soil extracts caused water turbidity and resulted in an abnormally high UV(254) in 1.2 and 0.45 microm filtrates. The reactivity of organic carbon fractions in forming THM was similar for the two soils, except that COC from the mineral soil was about half that of others. To obtain a more homogeneous solution for characterizing THM precursors, we recommend a 0.1 microm or smaller pore-size filter, especially for samples with high colloid concentrations.

Published

2004

7. Pressurized fluid extraction for quantitative recovery of chloroacetanilide and nitrogen heterocyclic herbicides in soil

Author

Ye Zhu, Fengmao Guo, K. Yanagihara, and Qing X. Li

Subjects

Chromatography, Herbicides, Nitrogen, Extraction (chemistry), Alachlor, General Chemistry, Hexazinone, chemistry.chemical_compound, Tebuthiuron, chemistry, Bromacil, Metribuzin, Heterocyclic Compounds, Environmental chemistry, Soil water, Acetamides, Acetone, Pressure, Soil Pollutants, General Agricultural and Biological Sciences

Abstract

Pressurized fluid extraction (PFE) is a new sample extraction method operated at elevated temperatures and pressures with liquid solvents. The use of PFE was investigated for the extraction of four Hawaiian clayey soils fortified with the selected chloroacetanilide and nitrogen heterocyclic herbicides Alachlor, Bromacil, Hexazinone, Metribuzin, and Tebuthiuron. The effects of operation temperature, pressure, flush volume, and static cycles on PFE performance were studied. Water was the most effective modifier of PFE for quantitative recoveries of the five herbicides in soils. The simple extraction method required pretreatment of the soil with 37.6% water and subsequent two-static-cycle extraction with a total of 32 mL of acetone at 1500 psi and 100 degrees C. Average recoveries of Alachlor, Bromacil, Hexazinone, Metribuzin, and Tebuthiuron ranged from 93 to 103% by the water-assisted PFE, compared with only 68-83% recoveries of the corresponding chemicals when no water was used. The extraction time and total organic solvent consumption were reduced from 18 h and 300 mL by Soxhlet to 22 min or less and 80 mL or less of organic solvent by PFE.

Published

2000