ID:
publications-2180
Type:
Peer reviewed articles
Year:
2021
Authors:
D. Tzohar, M. Moshelion, A. BenâGal
Title:
Compensatory hydraulic uptake of water by tomato due to variable rootâzone salinity
Venue/Journal:
Vadose Zone Journal
DOI:
10.1002/vzj2.20161
Research type:
Uncategorized
Water System:
Irrigation Systems
Technical Focus:
Abstract:
AbstractPlant root systems are exposed to spatial and temporal heterogeneity regarding water availability. In the longâterm, compensation, increased uptake by roots in areas with favorable conditions in response to decreased uptake in areas under stress, is driven by root growth and distribution. In the shortâterm (hoursâdays), compensative processes are less understood. We hypothesized hydraulic compensation where local lowered water availability is accompanied by increased uptake from areas where water remains available. Our objective was to quantify instantaneous hydraulic root uptake under conditions of differential water availability. Tomato (Solanum lycopersicum L.) plants were grown in splitâroot weighingâdrainage lysimeters in which each half of the roots could alternatively be exposed to shortâterm conditions of salinity. Uptake was quantified from each of the two root zone compartments. Oneâsided exposure to salinity immediately led to less uptake from the saltâaffected compartment and increased uptake from the nontreated compartment. Compensation occurred at salinity, caused by NaCl solution of 4 dS mâ1, that did not decrease uptake in plants with entire root systems exposed. At higher salinity, 6.44 dS mâ1, transpiration decreased by âŒ50% when the total root system was exposed. When only half of the roots were exposed, total uptake was maintained at levels of nonstressed plants with as much as 85% occurring from the nontreated compartment. The extent of compensation was not absolute and apparently a function of salinity, atmospheric demand, and duration of exposure. As long as there is no hydraulic restriction in other areas, temporary reduction in water availability in some parts of a tomato's root zone will not affect plantâscale transpiration.
Link with Projects:
773903
Link with Tools:
Related policies:
ID:
