Results of the latest research seeking solutions to soil water repellency have been revealed at Western Australia’s premier grains research forum.
Phil Ward from the CSIRO discussed the impact of no-till and residue retention systems, wet versus dry seeding, and the use of deep ripping on water repellent soils on the first day of the Grains Research and Development Corporation’s (GRDC) Grains Research Update held at Crown Perth on February 27 and 28.
“Soil water repellency affects up to 10 million hectares of sandy soils in southern and Western Australia and it leads to poor crop establishment, increased weed management costs and the risk of soil erosion,” Dr Ward said.
“Those tell-tale signs of dry patches of soil, even after substantial rainfall, are caused by plant waxes and microbes that mix with or coat soil particles, restricting the absorption of water.
“What we found in field trials at Munglinup and Pingrup is that rainfall can soak into the ground more effectively in no-till and stubble retention systems, ensuring better crop emergence.”
The GRDC-funded field trials, conducted in collaboration with the Department of Agriculture and Food (DAFWA), examined patterns of water movement into the soil and measured the annual impacts on crop emergence and grain yield.
Researchers also tested row placement (either between the previous crop rows, or close to previous crop rows), wet versus dry seeding, and the use of a surfactant to encourage water absorption.
“The combination of no-till and residue retention was found to preserve root pathways in the soil, allowing water to enter despite the water repellent soil layer,” Dr Ward said.
“However, these strategies must be practiced for several years before improvements to soil water, crop establishment and yield become evident.
“When used in tandem with intensive cultivation treatments such as deep ripping, this combination reduces the risk of soil erosion and creates new water entry pathways.”
At Munglinup, in a paddock with a long history of no-till and residue retention, treatments included residue removal by burning versus continued residue retention, and a single shallow (10cm) cultivation at seeding (CT) versus no-till (NT).
Treatments were applied annually to each plot for five years until 2012, when the entire trial reverted to no-till and stubble retention to assess the speed of recovery from cultivation and stubble burning.
At Pingrup, treatments included inter-row versus on-row seeding (using the iTILL® system), wet versus dry seeding, and furrow-applied surfactant versus no surfactant. Wet versus dry seeding was tested either side of a rainfall event in 2015 and using artificial rain shelters in 2016.
At both trials, soil water repellency (Molarity of Ethanol Droplet, MED) and soil carbon were measured several times a year, and soil water contents were measured in ‘in-row’ and ‘inter-row’ locations.
Dr Ward says the trials show that seeding crops on or near the old crop row promotes water entry through root pathways from the previous year’s crops, increasing moisture content in the furrows and improving crop emergence.
“Wetter furrows were also shown to promote microbial activity by wax-degrading bacteria, resulting in significantly lower water repellency than in the inter-row,” he said.
Dry sowing of water repellent soil should be avoided, and where practical, these soils should be sown later in the seeding program after the seasonal break, or directly after a rainfall event.
“If dry seeding a water repellent sand is unavoidable, sowing close to the previous year’s crop rows appears to give better results than the more conventional inter-row sowing,” said Dr Ward.
“This is due to reduced water repellency and increased water infiltration down old root pathways.”
Phil Ward, CSIRO
08 9333 6616
Natalie Lee, Cox Inall Communications
0427 189 827