Liquid bridges at the root-soil interface

Background The role of die root-soil interface on soil-plant water relations is unclear. Despite many experimental studies proved that the soil close to the root surface, the rhizosphere, has different properties compared to the adjacent bulk soil, the mechanisms underlying such differences are poor...

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Bibliographic Details
Published in:Plant and soil 2017-08, Vol.417 (1/2), p.1-15
Main Authors: Carminati, Andrea, Benard, P., Ahmed, M. A., Zarebanadkouki, M.
Format: Article
Language:English
Subjects:
Biomedical and Life Sciences
Continuity
Drying
Ecology
Exudation
Filaments
Hydraulic properties
Life Sciences
Liquid bridges
MARSCHNER REVIEW
Mucilage
Observations
Physical properties
Plant Physiology
Plant Sciences
Plant-soil relationships
Plant-water relationships
Porous media
Properties
Rhizosphere
Roots
Soil mechanics
Soil properties
Soil Science & Conservation
Soil solution
Soil stability
Soil water
Soils
Surface tension
Transpiration
Viscosity
Water potential
Water relations
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Summary:Background The role of die root-soil interface on soil-plant water relations is unclear. Despite many experimental studies proved that the soil close to the root surface, the rhizosphere, has different properties compared to the adjacent bulk soil, the mechanisms underlying such differences are poorly understood and the implications for plant-water relations remain largely speculative. Scope The objective of this review is to identify the key elements affecting water dynamics in the rhizosphere. Special attention is dedicated to the role of mucilage exuded by roots in shaping the hydraulic properties of the rhizosphere. We identified three key properties: 1) mucilage adsorbs water decreasing its water potential; 2) mucilage decreases the surface tension of the soil solution; 3) mucilage increases the viscosity of the soil solution. These three properties determine the retention and spatial configuration of the liquid phase in porous media. The increase in viscosity and the decrease in surface tension (quantified by the Ohnesorge number) allow the persistence of long liquid filaments even at very negative water potentials. At high mucilage concentrations these filaments form a network that creates an additional matric potential and maintains the continuity of the liquid phase during drying. Conclusion The biophysical interactions between mucilage and the pore space determine the physical properties of the rhizosphere. Mucilage forms a network that provides mechanical stability to soils upon drying and that maintains the continuity of the liquid phase across the soil-root interface. Such biophysical properties are functional to create an interconnected matrix that maintains the roots in contact with the soil, which is of particular importance when the soil is drying and the transpiration rate is high.
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-017-3227-8