Hydraulic redistribution by a dominant, warm‐desert phreatophyte: seasonal patterns and response to precipitation pulses

Hultine, Kevin R.; Scott, Russell L.; Cable, William; Goodrich, David C.; Williams, David G.

doi:10.1111/j.0269-8463.2004.00867.x

Cited by 125 publications

(137 citation statements)

References 29 publications

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“…For example, eucalypts can mine groundwater, and in the arid climate of Arizona, trees can tap water from 18 m below the surface because they have adjusted to a drier climate in former times. Mesquite trees in Arizona, when abundant, have been observed to redistribute surface soil moisture downward, in essence banking this water for later use and moving it below the reach of more shallow rooted inter-canopy competitors (Hultine et al, 2004). Vegetation change is often a localised change and the change effects are lost at larger scales.…”

Section: Catchment Processes and Flow Pathsmentioning

confidence: 99%

At what scales do climate variability and land cover change impact on flooding and low flows?

Blöschl

Ardoin‐Bardin

Bonell

et al. 2007

Hydrological Processes

331

254

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Section: Catchment Processes and Flow Pathsmentioning

confidence: 99%

At what scales do climate variability and land cover change impact on flooding and low flows?

Blöschl

Ardoin‐Bardin

Bonell

et al. 2007

Hydrological Processes

331

254

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“…In addition to this, the movement of water has also been found to occur in all directions from moist soils to drier soils [27]. Hydraulic redistribution is the process by which water is transferred and stored for plant use in periods of drought [28,29]. Caldwell and Richards [30] found that water egress from roots was occurring overnight to be taken from the soil from the recipient plant roots directly.…”

Section: Hydraulic Redistributionmentioning

confidence: 99%

Local Level Stormwater Harvesting and Reuse: A Practical Solution to the Water Security Challenges Faced by Urban Trees

Nichols

Lucke

2015

Sustainability

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Water Sensitive Urban Design (WSUD) treatment devices are often used to restore natural drainage properties in developed catchments. WSUD can make positive contributions to the restoration of natural ecosystem processes, by supporting trees and habitats in urban areas without taking up limited urban space. This paper reports on the development and testing of a new WSUD device, the Wicking Tank. It is designed to supply sufficient volumes of water to urban trees through periods of drought via synthetic wicks from an underground storage tank to support adequate tree health. Relying on gravity fed stormwater, and the natural capillarity, adhesion, and cohesion properties of water and the process of hydraulic redistribution, water is transferred from the tank and into the rhizosphere of the tree. Water demand is controlled passively by the water potential differential across the root zone. Proof of concept testing of the Wicking Tank has shown the device to successfully draw water into soil to support the ongoing survival of a potted plant for over 20 weeks. Substantial differences are anticipated between this proof of concept test and an in-situ field trial. A field-based demonstration style version of the Wicking Tank is planned for construction and testing in 2015.

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“…Over the last few decades, sap-flow sensors (Dugas et al, 1992;Allen and Grime, 1995;Hall et al, 1998) have had a major impact on plant level studies by allowing routine measurements of whole-plant transpiration and for diagnosing differences in sap flow in individual stems and roots (e.g. Hultine et al, 2004).…”

Section: Measurement Of Canopy Processesmentioning

confidence: 99%

Putting the "vap" into evaporation

Shuttleworth¹

2007

Hydrol. Earth Syst. Sci.

208

147

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In the spirit of the Special Issue of HESS to which it contributes, this paper documents the origin and development of the science of natural evaporation from land surfaces over the last 3035 years, since the symposium A View from the Watershed was held to commemorate the opening of the new Institute of Hydrology (IH) building in 1973. Important subsequent technical progress includes the ability to measure routinely the diurnal cycle of near-surface meteorological variables using automatic weather stations, and of surface energy and momentum exchanges using automated implementations of the Bowen Ratio/Energy Budget technique and the Eddy Correlation technique, along with the capability to estimate the fetch for which these measurements apply. These improvements have been complemented by new methods to measure the separate components of evaporation, including: the interception process using randomly relocated below-canopy gauges, transpiration fluxes from individual leaves/shoots using porometers and from plants/plant components using stem-flow gauges and soil evaporation using micro-lysimeters and soil moisture depletion methods. In recent years progress has been made in making theory-based areaaverage estimates of evaporation using scintillometers, and model-based area-average estimates by assembling many streams of relevant data into Land Data Assimilation Systems. Theoretical progress has been made in extending near-surface turbulence theory to accommodate the effect of the excess boundary layer resistance to leaf-to-air transfer of energy and mass fluxes relative to that for momentum, and to allow for observed shortcoming in stability factors in the transition layer immediately above vegetation. Controversy regarding the relative merits of multi-layer model and big leaf representations of whole-canopy exchanges has been resolved in favour of the latter approach. Important gaps in the theory of canopy-atmosphere interactions have been filled, including recognising the need, separately, to represent dry-canopy and wet-canopy evaporation in models and the capability to describe wet-to-dry canopy transitions as well as the ability to describe sparse vegetation canopies which only partly cover the underlying soil. There is progress in methods of estimating crop water requirements, but an important recommendation of this paper is that this progress should continue by introducing use of an effective stomatal resistance rather than crop factors. The paper draws attention to relevant theoretical insight on this issue. Progress in theoretical understanding of evaporation processes has been used in the creation of numerous Land Surface Parameterisations (LSPs), the models used to represent land-surface interaction in climate and weather forecast models, and there have been important advances in describing the behaviour of plant stomata in LSPs. A major investment over the last 25 years in conducting Large-Scale Field Experiments, the better to measure, understand and model coupled land-surface/atmosphere intera...

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Hydraulic redistribution by a dominant, warm‐desert phreatophyte: seasonal patterns and response to precipitation pulses

Cited by 125 publications

References 29 publications

At what scales do climate variability and land cover change impact on flooding and low flows?

At what scales do climate variability and land cover change impact on flooding and low flows?

Local Level Stormwater Harvesting and Reuse: A Practical Solution to the Water Security Challenges Faced by Urban Trees

Putting the "vap" into evaporation

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Hydraulic redistribution by a dominant, warm‐desert phreatophyte: seasonal patterns and response to precipitation pulses

Cited by 125 publications

References 29 publications

At what scales do climate variability and land cover change impact on flooding and low flows?

At what scales do climate variability and land cover change impact on flooding and low flows?

Local Level Stormwater Harvesting and Reuse: A Practical Solution to the Water Security Challenges Faced by Urban Trees

Putting the &quot;vap&quot; into evaporation

Contact Info

Product

Resources

About

Putting the "vap" into evaporation