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In a native pasture, landscape properties influence soil moisture more than grazing management

D. C. Mitchell A D , W. B. Badgery A , P. Cranney B , K. Broadfoot A , S. Priest C and D. Pickering A
+ Author Affiliations
- Author Affiliations

A NSW Department of Primary Industries, Orange Agricultural Institute, 1447 Forest Road, Orange, NSW 2800, Australia.

B Central Tablelands Local Land Services, Orange Agricultural Institute, 1447 Forest Road, Orange, NSW 2800, Australia.

C Primrose Valley, Kangaroobie Lane, Orange, NSW 2800, Australia.

D Corresponding author. Email: david.mitchell@dpi.nsw.gov.au

Animal Production Science 57(9) 1799-1811 https://doi.org/10.1071/AN16154
Submitted: 11 March 2016  Accepted: 9 May 2017   Published: 5 July 2017

Abstract

It has been proposed that changes to grazing systems, from continuous to rotational grazing, alter the pasture mass and composition, which are reflected in changes to stored soil water. Additionally, in highly variable landscapes, determining whether the variation in soil water is due to the inherent landscape properties rather than the imposed grazing management has long been a contentious argument. To address this question, soil moisture was measured across a highly variable landscape under three differing grazing treatments (1-, 4- and 20-paddock systems). From the soil-water measurements, plant-available water and plant-available water capacity were determined. Different production zones (high, medium and low) were identified in the landscape by visually estimating green herbage mass in late spring. There were no observed differences in the measured plant-available water capacity across the grazing treatments; however, significant differences occurred in plant-available water capacity across the three production zones (high-production zone, 114 mm; medium-production zone, 102 mm; low-production zone, 88 mm) within the study period. There appears to be a trend between the plant-available water capacity and near-surface gravel content as measured in production zones. The high production zones held more plant-available water than did the low production zones, enabling more biomass and longer pasture growth during spring and autumn. The plant-available water in the low production zones significantly decreased with time. In all, 22 of the 50 soil-moisture monitoring locations displayed high temporal stability and were identified as being catchment-average soil water-content monitoring locations. A majority of these locations occurred in the medium production zone, demonstrating that representative soil moisture can be measured in these landscapes.

Additional keywords: soil moisture, temporal stability, time-controlled grazing.


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