Root zone salinity and sodicity under seasonal rainfall due to feedback of decreasing hydraulic conductivity

Soil sodicity, where the soil cation exchange complex is occupied for a significant fraction by Na+, may lead to vulnerability to soil structure deterioration. With a root zone flow and salt transport model, we modeled the feedback effects of salt concentration (C) and exchangeable sodium percentage...

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Bibliographic Details
Published in:Water resources research 2014-12, Vol.50 (12), p.9432-9446
Main Authors: van der Zee, S. E. A. T. M., Shah, S. H. H., Vervoort, R. W.
Format: Article
Language:English
Subjects:
Accumulation
Annual variations
Buffers
california
Capillary flow
Cation exchange
Cation exchanging
Cations
Climate
Conductivity
Degradation
Direction
Drainage
Drought
Drought periods
Dynamical systems
Dynamics
ecohydrology
Feedback
Fluxes
Groundwater
Hydraulic conductivity
infiltration
irrigation
Leaching
management
quality
Rain
Rainfall
Root zone
Salinity
Salinity effects
Salt advection
Salts
saturated hydraulic conductivity
Seasonal rainfall
Seasonal variations
sodicity
Sodium
Soil
soil salinity
Soil structure
soil-moisture dynamics
Soils
stochastic hydrology
Surface hardness
System dynamics
systems
Time
transport
variability
Vulnerability
wastewater
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Summary:Soil sodicity, where the soil cation exchange complex is occupied for a significant fraction by Na+, may lead to vulnerability to soil structure deterioration. With a root zone flow and salt transport model, we modeled the feedback effects of salt concentration (C) and exchangeable sodium percentage (ESP) on saturated hydraulic conductivity Ks(C, ESP) for different groundwater depths and climates, using the functional approach of McNeal (1968). We assume that a decrease of Ks is practically irreversible at a time scale of decades. Representing climate with a Poisson rainfall process, the feedback hardly affects salt and sodium accumulation compared with the case that feedback is ignored. However, if salinity decreases, the much more buffered ESP stays at elevated values, while Ks decreases. This situation may develop if rainfall has a seasonal pattern where drought periods with accumulation of salts in the root zone alternate with wet rainfall periods in which salts are leached. Feedback that affects both drainage/leaching and capillary upward flow from groundwater, or only drainage, leads to opposing effects. If both fluxes are affected by sodicity‐induced degradation, this leads to reduced salinity (C) and sodicity (ESP), which suggests that the system dynamics and feedback oppose further degradation. Experiences in the field point in the same direction. Key Points: The rate of change of ESP is slower than for C For seasonal climates and full FB, the long‐term ESP becomes smaller For Poisson climate and elevated ESP, the reduction of Ks is insignificant
ISSN:0043-1397
1944-7973
DOI:10.1002/2013WR015208