Title

Defining Phreatophyte Response to Reduced Water Availability: Preliminary Investigations on the Use of Xylem Cavitation Vulnerability in Banksia Woodland Species

Document Type

Journal Article

Publisher

CSIRO Publishing

Faculty

Computing, Health and Science

School

Natural Sciences

RAS ID

4992

Comments

This article was originally published as: Froend, R. H., & Drake, P. L. (2006). Defining phreatophyte response to reduced water availability: preliminary investigations on the use of Xylem Cavitation vulnerability in Banksia woodland Species. Australian Journal of Botany, 54(2), 173-179. Original article available here

Abstract

The consideration of phreatophyte response to changes in water availability is important in identifying ecological water requirements in water-resource planning. Although much is known about water-source partitioning and intra- and interspecific variability in groundwater use by Banksia woodland species, little is known about the response of these species to groundwater draw-down. This paper describes a preliminary study into the use of xylem cavitation vulnerability as a measure of species response to reduced water availability. A response function and critical range in percentage loss of conductance is identified for four Banksia woodland overstorey species. Similarity in the vulnerability curves of B. attenuata R.Br. and B. menziesii R.Br. at low tensions supports the notion that they occupy a similar ecohydrological niche, as defined by their broad distributions relative to depth to groundwater. B. ilicifolia R.Br., however, as an obligate phreatophyte, has a range restricted to environments of higherwater availability and shallower depth to groundwater and this is reflected in greater vulnerability to cavitation (relative to other Banksia) at lower tensions. The wetland tree Melaleuca preissiana Schauer generally expressed a greater vulnerability at any given xylem water potential ( x). This paper identifies the range in x within which there is an elevated risk of tree mortality, and represents a first step towards quantifying the critical thresholds in the response of Banksia woodland species to reduced water availability.

 

Link to publisher version (DOI)

10.1071/BT05081