Comparing hydrological frameworks for simulating crop biomass, water and nitrogen dynamics in a tile drained soybean-corn system: Cascade vs computational approach

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dc.contributor.author

Smith, Ward

Qi, Zhiming

Grant, Brian

VanderZaag, Andrew

Desjardins, Ray

dc.date.accepted

2018-12-07

dc.date.accessioned

2025-10-08T19:11:39Z

dc.date.available

2025-10-08T19:11:39Z

dc.date.issued

2018-12-27

dc.date.submitted

2018-07-27

dc.description.abstract - en

Biophysical agricultural models are needed for assessing science-based mitigation options to improve the efficiency and sustainability of agricultural cropping systems. It is crucial that they can accurately simulate soil hydrology and nutrient flows which strongly influence crop growth, biogeochemical processes and water quality. The purpose of this study was to compare the performance of the DeNitrification DeComposition model (DNDC), which utilizes simplified hydrologic processes, to a more comprehensive water flow model, the Root Zone Water Quality Model (RZWQM2), to determine which processes are sufficient for simulating water and nitrogen dynamics and recommend improvements. Both models were calibrated and validated for simulating soil hydrology, nitrogen loss to tile drains and crop biomass using detailed observations from a corn (Zea mays L.) -soybean (Glycine max (L.) Merr.) rotation in Iowa, with and without cover crops. DNDC performed adequately across a wide range of metrics in comparison to a more hydrologically complex model. Soybean and corn yield, and corn biomass over the growing season were well simulated by both models (NRMSE < 25%). Soybean yields were also very well simulated by both models (NRMSE < 20%); however, soybean biomass was over-predicted by RZWQM2 in the validation treatments. The magnitude of winter rye biomass and N uptake was well simulated but the timing of growth initiation in the spring was inaccurate at times. The annual and monthly estimation of tile flow and nitrogen loss to tiles drains were well simulated by both models; however, RZWQM2 performed better for simulating soil water content, and the dynamics of daily water flow to tile drains (DNDC: NSE −0.32 to 0.24; RZWQM2: NSE 0.35–0.69). DNDC overestimated soil water content near the soil surface and underestimated it in the deeper profile. We recommend that developments be carried out for DNDC to include improved root density and penetration functions, a heterogeneous and deeper soil profile, a fluctuating water table and mechanistic tile drainage. However, the inclusion of computationally intensive processes needs to be assessed in context to improved accuracy weighed against the model’s broad applicability.

dc.identifier.citation

Smith, W., Qi, Z., Grant, B., VanderZaag, A., & Desjardins, R. (2019). Comparing hydrological frameworks for simulating crop biomass, water and nitrogen dynamics in a tile drained soybean-corn system: Cascade vs computational approach. Journal of Hydrology X, 2, 100015. https://doi.org/10.1016/j.hydroa.2018.100015

dc.identifier.doi

https://doi.org/10.1016/j.hydroa.2018.100015

dc.identifier.issn

2589-9155

dc.identifier.uri

https://open-science.canada.ca/handle/123456789/3923

dc.language.iso

en

dc.publisher - en

Elsevier B.V.

dc.publisher - fr

Elsevier B.V.

dc.rights - en

Creative Commons Attribution 4.0 International (CC BY 4.0)

dc.rights - fr

Creative Commons Attribution 4.0 International (CC BY 4.0)

dc.rights.uri - en

https://creativecommons.org/licenses/by/4.0/

dc.rights.uri - fr

https://creativecommons.org/licenses/by/4.0/deed.fr

dc.subject - en

Soil quality

Crops

Water quality

Agricultural technology

Computer programming

dc.subject - fr

Qualité des sols

Cultures

Qualité de l'eau

Technologie agricole

Programmation d'ordinateur

dc.subject.en - en

Soil quality

Crops

Water quality

Agricultural technology

Computer programming

dc.subject.fr - fr

Qualité des sols

Cultures

Qualité de l'eau

Technologie agricole

Programmation d'ordinateur

dc.title - en

Comparing hydrological frameworks for simulating crop biomass, water and nitrogen dynamics in a tile drained soybean-corn system: Cascade vs computational approach

dc.type - en

Article

dc.type - fr

Article

local.acceptedmanuscript.articlenum

100015

local.article.journaltitle - en

Journal of Hydrology X

local.article.journalvolume

2

local.peerreview - en

Yes

local.peerreview - fr

Oui

local.requestdoi - en

No

local.requestdoi - fr

No

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