A Comparison of Zero‐Order, First‐Order, and Monod Biotransformation Models

Bekins, Barbara A.; Warren, Ean; Godsy, E. Michael

doi:10.1111/j.1745-6584.1998.tb01091.x

Cited by 186 publications

(100 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…These systems can be characterized by a linear NO 3 -N concentration profile, which is often unrealistic in systems with longer residence times that allow NO 3 -N to become limited. The model assumes the system is closed, anoxic, completely or partially mixed, independent of hydraulic loading rates, and insignificantly influenced by other kinetic reactions occurring within the system [43]. The model can be expressed as [44]:…”

Section: Zero Order (Zo) Modelmentioning

confidence: 99%

“…Therefore, removal rates (J FO ) increase linearly with NO 3 -N concentration assuming removal efficiency does to not change in relation to NO 3 -N load [46]. The model also assumes that the substrate concentration is significantly smaller than the half-saturation constant (K s , the concentration supporting an uptake rate of 50% of the maximum rate), the system is well mixed, has no significant influences from water losses or gains, and is dependent on only one reactant [14,43,47,48]. The ρ FO , the mass transfer coefficient (cm d −1 ), accounts for the intrinsic ability for the soil to retain NO 3 -N by including depth, which is often ignored by using other removal rate constants (i.e., k (d −1 )) in first order decay model evaluations.…”

Section: First Order Decay (Fo) Modelmentioning

confidence: 99%

See 1 more Smart Citation

Comparison of Four Nitrate Removal Kinetic Models in Two Distinct Wetland Restoration Mesocosm Systems

Messer

Burchell

Bírgand

2017

Water

View full text Add to dashboard Cite

Abstract:The objective of the study was to determine the kinetic model that best fit observed nitrate removal rates at the mesocosm scale in order to determine ideal loading rates for two future wetland restorations slated to receive pulse flow agricultural drainage water. Four nitrate removal models were investigated: zero order, first order decay, efficiency loss, and Monod. Wetland mesocosms were constructed using the primary soil type (in triplicate) at each of the future wetland restoration sites. Eighteen mesocosm experiments were conducted over two years across seasons. Simulated drainage water was loaded into wetlands as batches, with target nitrate-N levels typically observed in agricultural drainage water (between 2.5 and 10 mg L −1 ). Nitrate-N removal observed during the experiments provided the basis for calibration and validation of the models. When the predictive strength of each of the four models was assessed, results indicated that the efficiency loss and first order decay models provided the strongest agreement between predicted and measured NO 3 -N removal rates, and the fit between the two models were comparable. Since the predictive power of these two models were similar, the less complicated first order decay model appeared to be the best choice in predicting appropriate loading rates for the future full-scale wetland restorations.

show abstract

Section: Zero Order (Zo) Modelmentioning

confidence: 99%

Section: First Order Decay (Fo) Modelmentioning

confidence: 99%

Comparison of Four Nitrate Removal Kinetic Models in Two Distinct Wetland Restoration Mesocosm Systems

Messer

Burchell

Bírgand

2017

Water

View full text Add to dashboard Cite

show abstract

“…(1) Sinkkonen and Paasivirta (2000), (2) Aronson and Howard (1997), (3) Suarez and Rifai (1999), 4) Rogers et al (2002), (5) Baresel et al (2006), (6) Baresel and Destouni (2007), (7) Destouni et al (2010), (8) Mulligan and Yong (2004), ( errors (Bekins et al, 1998;Suarez and Rifai, 1999;Washington and Cameron, 2001;Mulligan and Yong, 2004). Nevertheless, Table 2 demonstrates that the investigated λτ g range in this paper is relevant for a wide range of different environmental pollutants and characteristic catchment conditions; the latter because the investigated travel time pdfs bound a wide range of different possible catchment situations regarding advective transport and its associated uncertainties (see comparisons between different scenarios and catchment examples in Darracq et al, 2010a, b).…”

Section: 10mentioning

confidence: 99%

Diffuse hydrological mass transport through catchments: scenario analysis of coupled physical and biogeochemical uncertainty effects

Persson

Jarsjö

2011

Hydrol. Earth Syst. Sci.

View full text Add to dashboard Cite

Abstract. This paper quantifies and maps the effects of coupled physical and biogeochemical variability on diffuse hydrological mass transport through and from catchments. It further develops a scenario analysis approach and investigates its applicability for handling uncertainties about both physical and biogeochemical variability and their different possible cross-correlation. The approach enables identification of conservative assumptions, uncertainty ranges, as well as pollutant/nutrient release locations and situations for which further investigations are most needed in order to reduce the most important uncertainty effects. The present scenario results provide different statistical and geographic distributions of advective travel times for diffuse hydrological mass transport. The geographic mapping can be used to identify potential hotspot areas with large mass loading to downstream surface and coastal waters, as well as their opposite, potential lowest-impact areas within the catchment. Results for alternative travel time distributions show that neglect or underestimation of the physical advection variability, and in particular of those transport pathways with much shorter than average advective solute travel times, can lead to substantial underestimation of pollutant and nutrient loads to downstream surface and coastal waters. This is particularly true for relatively high catchment-characteristic product of average attenuation rate and average advective travel time, for which mass delivery would be near zero under assumed transport homogeneity but can be orders of magnitude higher for variable transport conditions. A scenario of high advection variability, with a significant fraction of relatively short travel times, combined with a relevant average Correspondence to: K. Persson (klas.persson@natgeo.su.se) biogeochemical mass attenuation rate, emerges consistently from the present results as a generally reasonable, conservative assumption for estimating maximum diffuse mass loading, when the prevailing physical and biogeochemical variability and cross-correlation are uncertain.

show abstract

“…In general, hydrocarbon biotransformation rates are compound-specific and reflect local biogeochemical conditions within a plume (Vroblesky, Chapelle, 1994;Chapelle et al, 1996) and the characteristics of the local microbiological consortia (Borden, Bedient, 1986;Bekins et al, 1998). Nevertheless, from a practical, field-oriented engineering perspective, a simple global first-order kinetic model is often used in site investigations (e.g., Wilson et al, 1995;Buscheck et al, 1996).…”

Section: Reactive Transport Model Idealizationmentioning

confidence: 99%

A Monte Carlo simulation method for assessing biotransformation effects on groundwater fuel hydrocarbon plume lengths

McNab

2001

Computers & Geosciences

View full text Add to dashboard Cite

A Comparison of Zero‐Order, First‐Order, and Monod Biotransformation Models

Cited by 186 publications

References 20 publications

Comparison of Four Nitrate Removal Kinetic Models in Two Distinct Wetland Restoration Mesocosm Systems

Comparison of Four Nitrate Removal Kinetic Models in Two Distinct Wetland Restoration Mesocosm Systems

Diffuse hydrological mass transport through catchments: scenario analysis of coupled physical and biogeochemical uncertainty effects

A Monte Carlo simulation method for assessing biotransformation effects on groundwater fuel hydrocarbon plume lengths

Contact Info

Product

Resources

About