BIOREMEDIATION OF NITRATE-CONTAMINATED SHALLOW SOILS USING WATER TABLE MANAGEMENT TECHNIQUES: NITRATE REMOVAL EFFICIENCY

Due to the extensive application of artificial nitrogen-based fertilizers on land, groundwater from the central part of Taiwan faces problems of increasing concentrations of nitrate, which were measured to be well above 30 mg/L all year round. For meeting the 10 mg/L nitrate standard, optimal operations for a heterotrophic denitrification pilot plant designed for drinking water treatment was investigated. Ethanol and phosphate were added for bacteria growing on anthracite to convert nitrate to nitrogen gas. Results showed that presence of high dissolved oxygen (around 4 mg/L) in the source water did not have a significantly negative effect on nitrogen removal. When operated under a C/N ratio of 1.88, which was recommended in the literature, nitrate removal efficiency was measured to be around 70%, sometimes up to 90%. However, the reactor often underwent severe clogging problems. When operated under C/N ratio of 1.0, denitrification efficiency decreased significantly to 30%. Finally, when operated under C/N ratio of 1.5, the nitrate content of the influent was almost completely reduced at the first one-third part of the bioreactor with an overall removal efficiency of 89–91%. Another advantage for operating with a C/N ratio of 1.5 is that only one-third of the biosolids was produced compared to a C/N value of 1.88.

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LINKFLOW, A WATER FLOW COMPUTER MODEL FOR WATER TABLE MANAGEMENT: PART 3. MODEL APPLICATION

Transactions of the ASAE ◽

10.13031/2013.21417 ◽

1997 ◽

Vol 40 (6) ◽

pp. 1543-1547 ◽

Cited By ~ 1

Author(s):

P. L. Havard ◽

S. O. Prasher ◽

R. B. Bonnell ◽

A. Madani

Keyword(s):

Water Flow ◽

Water Table ◽

Computer Model ◽

Model Application ◽

Water Table Management

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Soil and water table management effects on aluminum dynamics in an acid sulphate soil in Vietnam

Agriculture Ecosystems & Environment ◽

10.1016/s0167-8809(97)00158-8 ◽

1998 ◽

Vol 68 (3) ◽

pp. 255-262 ◽

Cited By ~ 30

Author(s):

L Minh

Keyword(s):

Water Table ◽

Acid Sulphate Soil ◽

Acid Sulphate ◽

Water Table Management ◽

Management Effects ◽

Soil And Water

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Biogeochemical indicators to evaluate pollutant removal efficiency in constructed wetlands

Water Science & Technology ◽

10.2166/wst.1997.0152 ◽

1997 ◽

Vol 35 (5) ◽

pp. 1-10 ◽

Cited By ~ 53

Author(s):

K. R. Reddy ◽

E. M. D'Angelo

Keyword(s):

Microbial Biomass ◽

Removal Efficiency ◽

Nitrate Removal ◽

Oxygen Demand ◽

Acid Soils ◽

Pollutant Removal ◽

Alkaline Soils ◽

Organic C ◽

Wetland Treatment ◽

Biogeochemical Indicators

Wetlands support several aerobic and anaerobic biogeochemical processes that regulate removal/retention of pollutants, which has encouraged the intentional use of wetlands for pollutant abatement. The purpose of this paper is to present a brief review of key processes regulating pollutant removal and identify potential indicators that can be measured to evaluate treatment efficiency. Carbon and toxic organic compound removal efficiency can be determined by measuring soil or water oxygen demand, microbial biomass, soil Eh and pH. Similarly, nitrate removal can be predicted by dissolved organic C and microbial biomass. Phosphorus retention can be described by the availability of reactive Fe and Al in acid soils and Ca and Mg in alkaline soils. Relationships between soil processes and indicators are useful tools to transfer mechanistic information between diverse types of wetland treatment systems.

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Simultaneous oxidation and reduction treatments of polluted water by a bio-electro reactor

Water Science & Technology ◽

10.2166/wst.1996.0187 ◽

1996 ◽

Vol 34 (9) ◽

pp. 101-108 ◽

Cited By ~ 11

Author(s):

M. Kuroda ◽

T. Watanabe ◽

Y. Umedu

Keyword(s):

Aqueous Solution ◽

Organic Matter ◽

Electric Current ◽

Removal Efficiency ◽

Concentration Ratio ◽

Nitrate Removal ◽

Hydrogen Gas ◽

Polluted Water ◽

Simultaneous Oxidation ◽

Denitrifying Microorganisms

Application of a bio-electro reactor for treatment of various kinds of polluted water was investigated experimentally. Aqueous solution of nitrate, ammonium and/or organic matter were used as synthetic polluted water. Denitrification of the nitrate polluted water without organic matter proceeded effectively by utilizing hydrogen gas produced by electrolysis of water in the reactor. The bio-electro reactor was also available for the treatment of nitrate polluted water containing organic matter when the C/N concentration ratio was up to 1.0 under the condition of 100 mA of applied electric current. The nitrate removal efficiency from nitrate polluted water containing acetate at C/N=1.0 was more than 90% at 5 hours of HRT and 80% even at 2.8 h HRT. For the treatment of ammonium polluted water, nitrification and denitrification proceeded simultaneously in a bio-electro reactor where nitrifying and denitrifying microorganisms were immobilized on the electrodes. The results obtained in this study suggested that the bio-electro reactor system was capable to application for oxidation and reduction treatments of the nitrate and ammonium polluted water.

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Water Table Management Reduces Tile Nitrate Loss in Continuous Corn and in a Soybean-Corn Rotation

The Scientific World JOURNAL ◽

10.1100/tsw.2001.268 ◽

2001 ◽

Vol 1 ◽

pp. 163-169 ◽

Cited By ~ 7

Author(s):

Craig F. Drury ◽

Chin S. Tan ◽

John D. Gaynor ◽

John W. Daniel Reynolds ◽

Thomas W. Welacky ◽

...

Keyword(s):

Drinking Water ◽

Water Table ◽

Nitrate Concentration ◽

Tile Drainage ◽

N Fertilizer ◽

Phase 2 ◽

Nitrate Loss ◽

Continuous Corn ◽

Water Table Management ◽

Drinking Water Guideline

Water table management systems can be designed to alleviate soil water excesses and deficits, as well as reduce nitrate leaching losses in tile discharge. With this in mind, a standard tile drainage (DR) system was compared over 8 years (1991 to 1999) to a controlled tile drainage/subirrigation (CDS) system on a low-slope (0.05 to 0.1%) Brookston clay loam soil (Typic Argiaquoll) in southwestern Ontario, Canada. In the CDS system, tile discharge was controlled to prevent excessive drainage, and water was pumped back up the tile lines (subirrigation) to replenish the crop root zone during water deficit periods. In the first phase of the study (1991 to 1994), continuous corn (Zea mays, L.) was grown with annual nitrogen (N) fertilizer inputs as per local soil test recommendations. In the second phase (1995 to 1999), a soybean (Glycine max L., Merr.)-corn rotation was used with N fertilizer added only during the two corn years. In Phase 1 when continuous corn was grown, CDS reduced total tile discharge by 26% and total nitrate loss in tile discharge by 55%, compared to DR. In addition, the 4-year flow weighted mean (FWM) nitrate concentration in tile discharge exceeded the Canadian drinking water guideline (10 mg N l–1) under DR (11.4 mg N l–1), but not under CDS (7.0 mg N l–1). In Phase 2 during the soybean-corn rotation, CDS reduced total tile discharge by 38% and total nitrate loss in tile discharge by 66%, relative to DR. The 4-year FWM nitrate concentration during Phase 2 in tile discharge was below the drinking water guideline for both DR (7.3 mg N l–1) and CDS (4.0 mg N l–1). During both phases of the experiment, the CDS treatment caused only minor increases in nitrate loss in surface runoff relative to DR. Hence CDS decreased FWM nitrate concentrations, total drainage water loss, and total nitrate loss in tile discharge relative to DR. In addition, soybean-corn rotation reduced FWM nitrate concentrations and total nitrate loss in tile discharge relative to continuous corn. CDS and crop rotations with reduced N fertilizer inputs can thus improve the quality of tile discharge water substantially.

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