High clay contents, dense soils, and spatial variability are the principal subsoil constraints to cropping the higher rainfall land in south-eastern Australia

MacEwan, Richard; Crawford, Douglas M.; Newton, P. J.; Clune, Tim

doi:10.1071/sr09076

Cited by 35 publications

(10 citation statements)

References 83 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These occupy large areas of the agricultural land in southern Australia and are characterized by a light-textured sandy, sandy-loam or loam soil, overlying dense clay subsoil (Chittleborough 1992). Root growth into the deeper layers of the clay subsoil is frequently limited by excessive soil density and strength, and low macro-porosity, and there can also be chemical constraints from salinity and sodicity in some duplex soils (MacEwan et al 2010). A feature of the physically constraining subsoil is that crop growth can be constrained by transient waterlogging in winter when rainfall exceeds evaporation, and then limited by water deficits as rainfall declines in mid to late spring.…”

Section: Introductionmentioning

confidence: 99%

Changes in pasture root growth and transpiration efficiency following the incorporation of organic manures into a clay subsoil

2011

View full text Add to dashboard Cite

Background & aim This study tested the hypothesis that manure incorporation in the top of the B horizon of a texture-contrast duplex soil would increase root growth and water uptake by pasture grasses. Methods It involved soil columns consisting of a sandy loam topsoil over a dense clay. Four soil treatments included (i) a control profile, and modifications to the upper 10 cm of the clay subsoil involving (ii) a lower bulk density and (iii) the incorporation of poultry and (iv) dairy manure into this layer. Italian ryegrass and prairie grass were grown in separate columns, over 3 growth cycles. Results Manure incorporation decreased root biomass by up to 40% in both grasses, without any reduction in shoot growth. Root distribution varied with roots proliferating in the manured-layers compared with the same layer without the manures, resulting in a doubling of the root length density in the manured layer. Shoot yields in the 2nd growth cycle were similar between treatments, yet there was lower transpiration from the shoots in the manure treatments. This meant that manure incorporation increased transpiration efficiency, as it changed the distribution and architecture of the roots. Conclusion Manure incorporation into subsoil increased transpiration efficiency, and root surface area, rather than shoot biomass, was the controlling factor for transpiration from the shoots of the grasses.

show abstract

Section: Introductionmentioning

confidence: 99%

Changes in pasture root growth and transpiration efficiency following the incorporation of organic manures into a clay subsoil

2011

View full text Add to dashboard Cite

show abstract

“…As a result, the previous simulation studies may be overestimating the value of modified root systems for many Australian cropping soils. For example, sodicity constraints have been reported for 59% of Victorian and 63% of South Australian arable land ( Ford et al , 1993 ) and are estimated to affect more than 26% of Queensland ( Dang et al , 2006 ; MacEwan et al , 2010 ) and around 50% of arable land nationally.…”

Section: Introductionmentioning

confidence: 99%

Farming system context drives the value of deep wheat roots in semi-arid environments

Lilley

Kirkegaard

2016

EXBOTJ

View full text Add to dashboard Cite

show abstract

“…• Changes in microbial community structure were due to movement of soil solution away from the amendment. Soils with dense, sodic clay subsoil dominate the dryland crop production zones of south-eastern Australia (MacEwan, Crawford, Newton, & Clune, 2010). These subsoils are naturally physically constrained and can severely limit plant growth by restricting root penetration and water use by plants (Adcock, McNeill, McDonald, & Armstrong, 2007;Zhang, Turner, Poole, & Simpson, 2006).…”

Section: Highlightsmentioning

confidence: 99%

Organic and inorganic amendments did not affect microbial community composition in the bulk soil differently but did change the relative abundance of selected taxa

Celestina

Sale

Tang

et al. 2019

European J Soil Science

View full text Add to dashboard Cite

Deep placement of organic amendments such as poultry litter and legume residues has been developed as a technique to ameliorate sodic clay subsoils in the south‐east Australian cropping region. It has been suggested that the soil microbial community plays a key role in this process of subsoil amelioration. A controlled environment experiment using repacked soil units was conducted to investigate changes in the microbial communities of subsoil treated with organic and inorganic amendments. Poultry litter, inorganic nutrients and wheat straw plus inorganic nutrients with equivalent total nutrient content (460 kg N ha−1, 210 kg P ha−1 and 330 kg K ha−1) were mixed into a central band and incubated for 21 days, followed by 126 days with wheat plants. Changes to bacterial and fungal communities in the bulk subsoil, 2–7 cm from the amended band, were assessed using next‐generation amplicon sequencing of the 16S and ITS rRNA genes. There were small but significant (p < 0.05) changes in bacterial and fungal community structure of the amended treatments, relative to the unamended control, which were linked to the movement of solutes away from the amended band. The three amendments did not affect microbial community composition differently in the bulk soil, although there were changes in the relative abundance of selected taxa. Our results suggest that changes in soil microbial communities in the bulk subsoil in this experimental system largely depended on movement of the soil solution through the profile. Highlights We characterized effect of amendments on microbial communities in the soil beyond the detritusphere. Microbial community of bulk soil was different in amended treatments from the unamended control. Amendments did not affect community composition differently but did change relative abundances of certain taxa. Changes in microbial community structure were due to movement of soil solution away from the amendment.

show abstract

High clay contents, dense soils, and spatial variability are the principal subsoil constraints to cropping the higher rainfall land in south-eastern Australia

Cited by 35 publications

References 83 publications

Changes in pasture root growth and transpiration efficiency following the incorporation of organic manures into a clay subsoil

Changes in pasture root growth and transpiration efficiency following the incorporation of organic manures into a clay subsoil

Farming system context drives the value of deep wheat roots in semi-arid environments

Organic and inorganic amendments did not affect microbial community composition in the bulk soil differently but did change the relative abundance of selected taxa

Contact Info

Product

Resources

About