Fx. Dunin et al., Can agricultural management emulate natural ecosystems in recharge controlin south eastern Australia?, AGROFOR SYS, 45(1-3), 1999, pp. 343-364
Water balance information at locations across southern Australia is analyse
d to identify mechanistic causes for higher water tables under agricultural
systems compared to natural vegetation. Contrasting patterns of water use
indicate pronounced physiological activity in summer by natural ecosystems
ensuring the persistence of the dominant perennial species. A strategy of t
empered water use during periods of rainfall excess in winter/spring enable
s seasonal carryover of soil water to be withdrawn by deep roots for summer
functioning. Characteristic patterns of water use by agricultural systems,
comprised mainly of determinant annual species, are truncated in time but
feature elevated peak rates coinciding with periods of maximum soil water a
vailability during the cooler months. Low seasonal vapour pressure deficit
explains the observed benefits of enhanced biomass production due to high w
ater use efficiency. The associated limited scope for soil water uptake car
ries the penalty of increased frequency of drainage and the subsequent reso
urce degradation currently associated with farmland. Inclusion of a perenni
al lucerne phase in rotation with crops confers environmental benefit throu
gh summer uptake from a rooting depth double that of crops. An effective bu
ffer is thus provided to restrict drainage under an ensuing cropping phase
in a manner that more closely emulates natural systems. Simulations of phas
e farming point to a halving in long term drainage. They suggest adoption o
ver a range of arable land units could cause local retreat of water tables
by 0.3 m y(-1) initially, leading to a new equilibrium level which would st
ill remain elevated with respect to that under natural vegetation.