Consequences of rainfall during summer–autumn fallow on available soil water and subsequent drainage in annual-based cropping systems
P. J. Dolling A D , I. R. P. Fillery B , P. R. Ward B , S. Asseng B and M. J. Robertson CA Department of Agriculture Western Australia, 10 Dore St, Katanning, WA 6317, Australia.
B CSIRO Plant Industry, PO Box 5, Wembley, WA 6913, Australia.
C CSIRO Sustainable Ecosystems, PO Box 5, Wembley, WA 6913, Australia.
D Corresponding author. Email: pdolling@agric.wa.gov.au
Australian Journal of Agricultural Research 57(3) 281-296 https://doi.org/10.1071/AR04103
Submitted: 6 May 2004 Accepted: 12 November 2005 Published: 31 March 2006
Abstract
This paper investigates factors controlling soil water content changes during the non-growing summer–autumn season or fallow (December–May) in annual farming systems in southern Western Australia. This was achieved by examining variation in available soil water storage to a depth of 1.0–1.5 m at 3 sites within 13 seasons. Reasons for the variation were examined using the Agricultural Production Systems Simulator (APSIM). This paper also investigated whether water accumulation during the summer–autumn period (fallow) contributed to drainage during the following growing season (May–November). This was achieved by determining the relationship between soil water content at the end of the fallow period (1 May) and the amount of drainage below 2.5 m by using APSIM coupled to historical weather records at 3 locations.
At the end of the fallow, 24 mm (or 25%) of rain falling during the fallow was retained in the soil. Evaporation was the main loss of soil water during fallow periods (mean of 60 mm). Other losses included transpiration from plant cover (mean of 12 mm) and drainage below the root zone and runoff (combined mean of 13 mm). Evaporation and transpiration losses of soil water were concentrated in the surface 0.3 m. The use of APSIM to determine changes in the soil water content during the fallow indicated the importance of plants to soil water losses, the potential for higher evaporation than previously reported, and the possibility of an extended period (4–6 weeks) of drainage in sandy soils after large rainfall events (>50 mm).
Soil water accumulation during the fallow period had a significant effect on simulated drainage under wheat in the following growing season. By the end of fallow there was limited ability of the soil to store water before drainage occurred due to rainfall during the fallow and the small soil water deficit under annual farming systems (1–67 mm). A 1-mm increase in soil wetness at the end of the fallow resulted in a 0.7–1-mm increase in simulated drainage during the growing season.
Acknowledgments
We thank Frank Dunin, CSIRO Plant Industry, for valuable discussions, Prof. Phil Cocks, CRC for Plant-based Management of Dryland Salinity, Dr Damian Barrett, CSIRO Plant Industry, and Dr Anthony Ringrose-Voase, CSIRO Land and Water, for their comments on an earlier draft. The Grains Research and Development Corporation, the Department of Agriculture Western Australia, and the CRC for Plant-based Management of Dryland Salinity provided support for this project.
Alizai HU, Hulbert LC
(1970) Effects of soil texture on evaporative loss and available water in semi-arid climates. Soil Science 110, 328–332.
Anderson GC,
Fillery IRP,
Dolling PJ, Asseng S
(1998a) Nitrogen and water flows under pasture–wheat and lupin–wheat rotations in deep sands in Western Australia. 1. Nitrogen fixation in legumes, net N mineralisation, and utilisation of soil-derived nitrogen. Australian Journal of Agricultural Research 49, 329–343.
| Crossref | GoogleScholarGoogle Scholar |
Anderson GC,
Fillery IRP,
Dunin FX,
Dolling PJ, Asseng S
(1998b) Nitrogen and water flows under pasture–wheat and lupin–wheat rotations in deep sands in Western Australia. 2. Drainage and nitrate leaching. Australian Journal of Agricultural Research 49, 345–361.
| Crossref | GoogleScholarGoogle Scholar |
Asseng S,
Dunin FX,
Fillery IRP,
Tennant D, Keating BA
(2001b) Potential deep drainage under wheat crops in a Mediterranean climate. II. Management opportunities to control drainage. Australian Journal of Agricultural Research 52, 57–66.
| Crossref | GoogleScholarGoogle Scholar |
Asseng S,
Fillery IRP,
Anderson GC,
Dolling PJ, Dunin FX
(1998a) Use of the APSIM wheat model to predict yield, drainage, and NO3
– leaching for a deep sand. Australian Journal of Agricultural Research 49, 363–377.
| Crossref | GoogleScholarGoogle Scholar |
Asseng S,
Fillery IRP,
Dunin FX,
Keating BA, Meinke H
(2001a) Potential deep drainage under wheat crops in a Mediterranean climate. I. Temporal and spatial variability. Australian Journal of Agricultural Research 52, 45–56.
| Crossref | GoogleScholarGoogle Scholar |
Asseng S,
Keating BA,
Fillery IRP,
Gregory PJ,
Bowden JW,
Turner NC,
Palta JA, Abrecht DG
(1998b) Performance of the APSIM-wheat model in Western Australia. Field Crops Research 57, 163–179.
| Crossref | GoogleScholarGoogle Scholar |
Asseng S,
Turner NC, Keating BA
(2001c) Analysis of water- and nitrogen-use efficiency of wheat in a Meditterranean climate. Plant and Soil 233, 127–143.
| Crossref | GoogleScholarGoogle Scholar |
Carbon BA
(1975) Redistribution of water following precipitation on previously dry sand soils. Australian Journal of Soil Research 13, 13–19.
| Crossref | GoogleScholarGoogle Scholar |
Clewett, JF ,
Smith, PG ,
Partridge, IJ ,
George, DA ,
and
Peacock, A (1999).
Dalgliesh NP, Cawthray S
(1998) Determining plant available water capacity. ‘Soil matters: monitoring soil water and nutrients in dryland farming’ (Eds NP Dalgliesh, MA Foale)
pp. 71–91. (CSIRO, Australia: Toowoomba, Qld)
Dimes JP
(1996) Simulation of mineral N supply to no-till crops in the semi-arid tropics. PhD thesis, Griffith University, Qld, Australia.
Dracup M,
Belford RK, Gregory PJ
(1992) Constraints to root growth of wheat and lupin crops in duplex soils. Australian Journal of Experimental Agriculture 32, 947–961.
| Crossref | GoogleScholarGoogle Scholar |
Dunin FX
(2002) Integrating agroforestry and perennial pastures to mitigate water logging and secondary salinity. Agricultural Water Management 53, 259–270.
| Crossref | GoogleScholarGoogle Scholar |
Dunin FX,
Smith CJ,
Zegelin S,
Leuning R,
Denmead OT, Poss R
(2001) Water balance shifts during a crop rotation involving lucerne. Australian Journal of Agricultural Research 52, 247–261.
| Crossref | GoogleScholarGoogle Scholar |
Farrington P, Salama RB
(1996) Controlling dryland salinity by planting trees in the best hydrogeological setting. Land Degradation & Development 7, 183–204.
| Crossref | GoogleScholarGoogle Scholar |
Fillery IRP
(2000) Does the inclusion of perennials in pastures reduce drainage and nitrate leaching in acidic sandy soils of the Mediterranean climate zone of Australia? ‘Australian and New Zealand 2nd Joint Soils Conference: New horizons for a new century’ (Ed. J Adams ,
A Metherell )
pp. 105–106. (New Zealand Society of Soil Science: Lincoln, NZ)
Fischer RA, Armstrong JS
(1990) Simulation of soil water storage and sowing day probabilities with fallow and no-fallow in southern New South Wales: II. Stochasticity and management tactics. Agricultural Systems 33, 241–255.
| Crossref | GoogleScholarGoogle Scholar |
Fischer RA,
Armstrong JS, Stapper M
(1990) Simulation of soil water storage and sowing day probabilities with fallow and no-fallow in southern New South Wales: I. Model and long term mean effects. Agricultural Systems 33, 215–240.
| Crossref | GoogleScholarGoogle Scholar |
GENSTAT 5 Committee (1993).
George R,
McFarlane D, Nulsen B
(1997) Salinity threatens the viability of agriculture and ecosystems in Western Australia. Hydrogeology Journal 5, 6–21.
| Crossref | GoogleScholarGoogle Scholar |
George RJ
(1992) Hydraulic properties of groundwater systems in the saprolite and sediments of the wheatbelt, Western Australia. Journal of Hydrology 130, 251–278.
| Crossref | GoogleScholarGoogle Scholar |
Greacen EL
(1983) Physical properties and water relations: soil mechanical properties and water movement. ‘Soils: an Australian viewpoint’ pp. 499–507. (Division of Soils, CSIRO: Melbourne, Vic.)
Gregory PJ,
Poss R,
Eastham J, Micen S
(1995) Use of time domain reflectometry (TDR) to measure the water content of sandy soils. Australian Journal of Soil Research 33, 265–276.
| Crossref | GoogleScholarGoogle Scholar |
Hatton TJ, Nulsen RA
(1999) Towards achieving functional ecosystem mimicry with respect to water cycling in southern Australian agriculture. Agroforestry Systems 45, 203–214.
| Crossref | GoogleScholarGoogle Scholar |
Hatton TJ,
Ruprecht J, George RJ
(2003) Preclearing hydrology of the Western Australian wheatbelt: target for the future? Plant and Soil 257, 341–356.
| Crossref | GoogleScholarGoogle Scholar |
Isbell, RF (1996).
Jalota SK, Prihar SS
(1986) Effects of atmospheric evaporativity, soil type and redistribution time on evaporation from bare soil. Australian Journal of Soil Research 24, 357–366.
| Crossref | GoogleScholarGoogle Scholar |
Keating BA,
Carberry PS,
Hammer GL,
Probert ME, Robertson MJ ,
et al
.
(2003) An overview of APSIM, a model designed for farming systems simulation. European Journal of Agronomy 18, 267–288.
| Crossref | GoogleScholarGoogle Scholar |
Keating BA, McCown RL, Cresswell HP
(1995) Paddock-scale models and catchment-scale problems: the role of APSIM in the Liverpool Plains. ‘Proceedings of the International Congress on Modelling and Simulation, Vol. 1: Agriculture, catchment hydrology and industry’ (Ed. P Binning ,
H Bridgman ,
B Williams )
pp. 158–165. (The University of Newcastle: Newcastle, NSW)
Peck AJ, Hurle DH
(1973) Chloride balance of some farmed and forested catchments in south-western Australia. Water Resources Research 3, 648–657.
Probert ME,
Dimes J,
Keating BA,
Dalal RC, Strong WM
(1998) APSIM__(tm)s water and nitrogen modules and simulation of the dynamics of water and nitrogen in fallow systems. Agricultural Systems 56, 1–28.
| Crossref | GoogleScholarGoogle Scholar |
Probert ME,
Keating BA,
Thompson JP, Parton WJ
(1995) Modelling water, nitrogen, and crop yield for a long-term fallow management experiment. Australian Journal of Experimental Agriculture 35, 941–950.
| Crossref | GoogleScholarGoogle Scholar |
Reichardt K,
Nielsen DR, Biggar JW
(1972) Scaling of horizontal infiltration into homogeneous soils. Soil Science Society of America Proceedings 36, 241–245.
Ritchie JT
(1972) Model for predicting evaporation from a row crop with incomplete cover. Water Resources Research 8, 1204–1213.
Ritchie JT, Crum J
(1989) Converting soil survey characterization data into IBSNAT crop model input. ‘Land qualities in space and time’ (Eds J Bouma, AK Bregt, B Williams)
pp. 155–167. (Pudoc: Wageningen, The Netherlands)
Ritchie JT, Kiniry JR, Jones CA, Dyke PT
(1986) Model inputs. ‘CERES-Maize: a simulation model of maize growth and development’ (Eds CA Jones, JR Kiniry, B Williams)
pp. 37–48. (Texas A&M University Press: College Station, TX)
Schoknecht, N (2001).
Schultz JE
(1971) Soil water changes under fallow–crop treatments in relation to soil type, rainfall and yield of wheat. Australian Journal of Experimental Agriculture and Animal Husbandry 11, 236–242.
| Crossref | GoogleScholarGoogle Scholar |
Tennant D, Hall D
(2001) Improving water use of annual crops and pastures–limitations and opportunities in Western Australia. Australian Journal of Agricultural Research 52, 171–182.
| Crossref | GoogleScholarGoogle Scholar |
Wallach D, Goffinet B
(1989) Mean square error of prediction as a criterion for evaluating and comparing system models. Ecological Modelling 44, 299–306.
| Crossref | GoogleScholarGoogle Scholar |
Ward PR,
Dunin FX, Micin SF
(2001) Water balance of annual and perennial pastures on a duplex soil in a Mediterranean environment. Australian Journal of Agricultural Research 52, 203–209.
| Crossref | GoogleScholarGoogle Scholar |
Ward PR,
Dunin FX, Micin SF
(2002) Water use and root growth by annual and perennial pastures and subsequent crops in a phase rotation. Agricultural Water Management 53, 83–97.
| Crossref | GoogleScholarGoogle Scholar |
Williams J
(1983) Physical properties and water relations: soil hydrology. ‘Soils: an Australian viewpoint’ pp. 507–530. (Division of Soils, CSIRO: Melbourne, Vic.)
Williamson DR,
Stokes RA, Ruprecht JK
(1987) Response of input and output of water and chloride to clearing for agriculture. Journal of Hydrology 94, 1–28.
| Crossref | GoogleScholarGoogle Scholar |