Carbon and nitrogen dynamics and greenhouse gas emissions in constructed  wetlands treating wastewater: a review

Jahangir, M. M. R.; Richards, Karl G.; Healy, Mark G.; Gill, Laurence; Müller, Christoph; Johnston, Paul; Fenton, Owen

doi:10.5194/hess-20-109-2016

Cited by 62 publications

(15 citation statements)

References 106 publications

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“…In order to enhance the success of wetland creation and restoration attempts, a better understanding of abiotic and biotic controls on wetland structure and function is required. Hydrology is the ultimate driver of wetland structure and function, and variations in surface water depth and duration of saturation regulate soil and water chemistry by determining oxygen availability and soil redox status; this indirectly controls nutrient availability for competing plants and microorganisms (Jahangir et al 2016;Song et al 2012), and directly controls the number, type, and distribution of individual plant species (Gurnell et al 2012;Zhang et al 2012). The resulting plant communities provide food and habitat for wetland herbivores, such as waterfowl, which choose their habitats based on water depth and resource availability (Bino et al 2014;Pickens and King 2014).…”

Section: Introductionmentioning

confidence: 99%

Divergent impact of grazing on plant communities of created wetlands with varying hydrology and antecedent land use

Lodge

Tyler

2020

Wetlands Ecol Manage

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Section: Introductionmentioning

confidence: 99%

Divergent impact of grazing on plant communities of created wetlands with varying hydrology and antecedent land use

Lodge

Tyler

2020

Wetlands Ecol Manage

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“…Microbes derive energy and carbon from the organic matter added through the wastewater into the soil. Fluctuation in the microbes' population and diversity are cumulatively influenced by the altering physical and chemical properties of the soil treated with wastewater [20]. Activity of the microbes leads to release of some acids which dissolve the organic carbon compounds to simpler forms.…”

Section: Introductionmentioning

confidence: 99%

Effect of Different Wastewaters on Carbon and Nitrogen Dynamics in Soils of North Karnataka, India

et al. 2017

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A study was conducted to evaluate the effect of bio-methanated distillery spentwash, paper mill, soft drink factory and domestic sewage wastewaters on carbon and nitrogen dynamics in red, lateritic, and black soils of north Karnataka. Application of wastewaters from different sources influenced the carbon and nitrogen fractions across treated soils. Water-soluble carbon, labile carbon and organic carbon were significantly higher in bio-methanated distillery spentwash-treated soils. Wide variations in nitrogen fractions NH 4 ? -N, NO 3 --N were recorded under the influence of different wastewaters across the treated soils. Irrespective of the soil types, content of organic carbon and nitrogen fractions followed the order bio-methanated distillery spentwash [ paper mill [ domestic wastewater C soft drink factory wastewater. Higher values of carbon and nitrogen fractions were observed in the surface layers (0-15 cm) in comparison with lower depths. Enumeration of the bacteria, fungi, actinomycetes, N 2 -fixers and P-solubilizers indicated higher microbial load in bio-methanated spentwash application followed by paper mill wastewater application. Microbial load was highly concentrated in the surface layer (0-15 cm) across the soils and wastewaters evaluated. The bacterial count in treated soils was double that of fresh water-treated soils. Among the soils used in the study, maximum bacteria, actinomycetes and P-solubilizers count were recorded in black soil under the influence of the bio-methanated spentwash.

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“…Compared to surface flow wastewater treatment wetlands receiving municipal or agricultural runoff, CO 2 emissions at our study wetland in flooded plots were similar but approximately 95% lower in shallow land plots (Jahangir et al, 2016;Mander et al, 2014). In contrast, CH 4 emissions at our study wetland had similar CH 4 rates in shallow land plots when compared to wastewater treatment wetlands, but approximately 94% greater emissions in flooded plots compared to wastewater treatment wetlands (Jahangir et al, 2016;Mander et al, 2014). In terms of GWP, flooded plots in our study wetland have a GWP that is 98% greater than in wastewater treatment wetlands.…”

Section: Discussionmentioning

confidence: 61%

A microbial perspective on balancing trade-offs in ecosystem functions in a constructed stormwater wetland

Bledsoe

Bean

Austin

et al. 2020

Ecological Engineering

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Green stormwater infrastructure, such as constructed wetlands (CWs), is a type of stormwater control measure that can decrease nutrient and pollutant loads from urban stormwater runoff. Wetland soil microorganisms provide nutrient and pollutant removal benefits which can also result in ecosystem disservices such as greenhouse gas (GHG) emissions and can inadvertently exacerbate climate change. Microbial respiration by facultative anaerobes in anoxic conditions is the primary pathway for nitrogen removal (benefit). Similar anoxic conditions that support denitrifying microorganisms can also support obligate anaerobes that produce methane (CH 4 ) via methanogenesis (disservice). We examined nitrogen removal potential, GHG production, and microbial community structure within permanently flooded and shallow land or temporarily-flooded areas of a stormwater CW to identify zones for CW design optimization.Results indicate that permanently flooded zones compared to shallow land zones are greater sources of CH 4 emissions (80.80 ± 118.31, 2.32 ± 9.33 mg CH 4 -C m -2 hr -1 , respectively) and emit more carbon to the atmosphere (7161.27 kg CO 2 , 93.20 kg CO 2 equivalents, respectively). However, nitrogen removal potential rates were similar across both flooded and shallow land zones (24.45 ± 20.18, 20.29 ± 15.14 ng N 2 O-N hr -1 g -1 dry soil, respectively). At this particular CW, reduction of permanently flooded zones within the wetland could decrease GHG emissions (disservice) without limiting nitrogen removal (benefit) potential of the wetland. Holistic development and design of stormwater control measures, which account for microbial activity, provides the opportunity to maximize benefits (i.e., nutrient and pollutant removal) and reduce disservices (i.e., GHG emissions) of green stormwater infrastructure.

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Carbon and nitrogen dynamics and greenhouse gas emissions in constructed wetlands treating wastewater: a review

Cited by 62 publications

References 106 publications

Divergent impact of grazing on plant communities of created wetlands with varying hydrology and antecedent land use

Divergent impact of grazing on plant communities of created wetlands with varying hydrology and antecedent land use

Effect of Different Wastewaters on Carbon and Nitrogen Dynamics in Soils of North Karnataka, India

A microbial perspective on balancing trade-offs in ecosystem functions in a constructed stormwater wetland

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