Diel plant water use and competitive soil cation exchange interact to enhance NH4 + and K+ availability in the rhizosphere

Espeleta, Javier F.; Cardon, Zoë G.; Mayer, K. Ulrich; Neumann, Rebecca B.

doi:10.1007/s11104-016-3089-5

Cited by 19 publications

(20 citation statements)

References 63 publications

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“…Rhizosphere oxygen concentration also likely follows a diel pattern that could partially control the activity of rhizosphere-associated microbes (42). Modeling efforts suggest that diel changes in water flow through the rhizosphere (43) would have a big impact on oxygen concentration. Active root and microbial growth in the rhizosphere may also create oxygen depletion zones within the rhizosphere (44).…”

Section: Figmentioning

confidence: 99%

To Fix or Not To Fix: Controls on Free-Living Nitrogen Fixation in the Rhizosphere

Smercina

Evans

Friesen

et al. 2019

Appl Environ Microbiol

132

137

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Section: Figmentioning

confidence: 99%

To Fix or Not To Fix: Controls on Free-Living Nitrogen Fixation in the Rhizosphere

Smercina

Evans

Friesen

et al. 2019

Appl Environ Microbiol

132

137

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“…The root uptake of nutrient is assumed to be an active uptake process as opposed to a passive process where solutes are simply taken up with the porewater by the roots. The active uptake rate is represented by a Michaelis-Menten expression (Somma et al 1998;Wu et al 2007;Espeleta et al 2017) in this model as shown in the following equation:…”

Section: Root Water Uptake Modelmentioning

confidence: 99%

“…Using a simple 1D model given prescribed water potential at soil-root boundary, Espeleta et al (2017) found that competitive cation exchange enabled NH 4 + and K + from soil to be desorbed from soil exchange sites and made available for plant use when low-demand cations such as Ca 2+ , Mg 2+ , and Na + accumulated near roots during water uptake. To simulate competitive ion exchange in 3D, cation exchange reactions (Table 1) and root nutrient uptake were included in our model.…”

Section: Competitive Cation Exchangementioning

confidence: 99%

“…The longitudinal and transverse dispersivities are 0.1 cm and 0.01 cm, respectively. The other input parameters are taken from Espeleta et al (2017) and shown in Table 2 for completeness. Cl − is a conservative tracer (assumed to not be taken up by the root and not be reactive) in this simulation, included for charge balance.…”

Section: Competitive Cation Exchangementioning

confidence: 99%

“…Three-dimensional (3D) models can better resolve the spatial distribution of water and nutrient resulting from interactions between individual roots and the local soil hydrobiogeochemistry (Garrigues et al 2006;Manoli et al 2014). On the other hand, simulations of nutrient dynamics are mainly limited to one and two dimensions (Espeleta et al 2017;Mollier et al 2008;Nietfeld and Prenzel 2015), or 3D non-reactive nutrient uptake, explicitly taking into account the geometry of the plant root system (Clausnitzer and Hopmans 1994;Dunbabin et al 2004;Dunbabin et al 2006;Leitner et al 2010c;Simunek and Hopmans 2009;Tournier et al 2015). The model by Gérard et al (2017) was the first to couple a root system architecture model with a multicomponent reactive transport model using a macroscopic approach.…”

Section: Introductionmentioning

confidence: 99%

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An efficient three-dimensional rhizosphere modeling capability to study the effect of root system architecture on soil water and reactive transport

et al. 2019

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Aims The objective of this research was to develop a three-dimensional (3D) rhizosphere modeling capability for plant-soil interactions by integrating plant biophysics, water and ion uptake and release from individual roots, variably saturated flow, and multicomponent reactive transport in soil. Methods We combined open source software for simulating plant and soil interactions with parallel computing technology to address highly-resolved root system architecture (RSA) and coupled hydrobiogeochemical processes in soil. The new simulation capability was demonstrated on a model grass, Brachypodium distachyon. Results In our simulation, the availability of water and nutrients for root uptake is controlled by the interplay between 1) transpiration-driven cycles of water uptake, root zone saturation and desaturation; 2) hydraulic redistribution; 3) multicomponent competitive ion exchange; 4) buildup of ions not taken up during kinetic nutrient uptake; and 5) advection, dispersion, and diffusion of ions in the soil. The uptake of water and ions by individual roots leads to dynamic, local gradients in ion concentrations. Conclusion By integrating the processes that control the fluxes of water and nutrients in the rhizosphere, the modeling capability we developed will enable exploration of alternative RSAs and function to advance the understanding of the coupled hydro-biogeochemical processes within the rhizosphere.

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Coupling non‐invasive imaging and reactive transport modeling to investigate water and oxygen dynamics in the root zone

Bereswill

Gatz-Miller

et al. 2023

Vadose Zone Journal

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Oxygen (O2) availability in soils is vital for plant growth and productivity. The transport and consumption of O2 in the root zone is closely linked to soil moisture content, the spatial distribution of roots, as well as structure and heterogeneity of the surrounding soil. In this study, we measure three‐dimensional root system architecture and the spatiotemporal dynamics of soil moisture (θ) and O2 concentrations in the root zone of maize (Zea mays) via non‐invasive imaging, and then construct and parameterize a reactive transport model based on the experimental data. The combination of three non‐invasive imaging methods allowed for a direct comparison of simulation results with observations at high spatial and temporal resolution. In three different modeling scenarios, we investigated how the results obtained for different levels of conceptual complexity in the model were able to match measured θ and O2 concentration patterns. We found that the modeling scenario that considers heterogeneous soil structure and spatial variability of hydraulic parameters (permeability, porosity, and van Genuchten α and n), better reproduced the measured θ and O2 patterns relative to a simple model with a homogenous soil domain. The results from our combined imaging and modeling analysis reveal that experimental O2 and water dynamics can be reproduced quantitatively in a reactive transport model, and that O2 and water dynamics are best characterized when conditions unique to the specific system beyond the distribution of roots, such as soil structure and its effect on water saturation and macroscopic gas transport pathways, are considered.

show abstract

Diel plant water use and competitive soil cation exchange interact to enhance NH4 + and K+ availability in the rhizosphere

Cited by 19 publications

References 63 publications

To Fix or Not To Fix: Controls on Free-Living Nitrogen Fixation in the Rhizosphere

To Fix or Not To Fix: Controls on Free-Living Nitrogen Fixation in the Rhizosphere

An efficient three-dimensional rhizosphere modeling capability to study the effect of root system architecture on soil water and reactive transport

Coupling non‐invasive imaging and reactive transport modeling to investigate water and oxygen dynamics in the root zone

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