Perennial pastures for recharge control in temperate drought-prone environments. Part 2: soil drying capacity of key species

Hayes, Richard; Dear, Brian; Conyers, Mark; Virgona, James; Tidd, Justin

doi:10.1080/00288233.2010.525784

Cited by 17 publications

(9 citation statements)

References 34 publications

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“…Hayes et al. (2010b) also reported little change in SWC below 0.75 m for a range of summer and winter active forage species.…”

Section: Discussionmentioning

confidence: 94%

“…A density of 1 plant per m 2 was too low to effectively and efficiently use the resources available (e.g., Hayes et al., 2010b; McCaskill & Kearney, ) and was ranked lowest for all parameters measured throughout the experiment (with the exception of root depth during year 3). Digit grass at a plant density of 4 plants per m 2 was ranked low during year 1 and 2, but as the plants developed and crowns increased, this density had similar hydrologic and growth responses to the higher density swards, and over the duration of the experiment showed the highest WUE.…”

Section: Discussionmentioning

confidence: 99%

“…A grazed perennial pasture requires a sufficient plant population to achieve both production and sustainability goals: high herbage accumulation and persistence (Hayes et al., ,b; McCaskill & Kearney, ) by maximizing soil water usage (rooting depth and extraction); having a dry profile in autumn to store winter rainfall (Hayes et al., 2010b; McCaskill & Kearney, ); and having high ground cover to reduce weeds (Dear, Virgona, Sandral, Swan, & Orchard, ; McCaskill & Kearney, ), minimize runoff (Murphy, Lodge, & Harden, ) and maximize infiltration (Murphy et al., ). There is also a threshold plant density, below which a species is not able to achieve these goals (e.g., Dolling, Lyons, & Latta, ; Hayes et al., ,b; McCaskill & Kearney, ; Virgona, ). Our data indicated that digit grass with density of 1 plant per m 2 was below this threshold, while densities ≥4 plants per m 2 achieved both herbage accumulation and sustainability goals.…”

Section: Discussionmentioning

confidence: 99%

“…A density of 1 plant per m 2 was too low to effectively and efficiently use the resources available (e.g., Hayes et al, 2010b;McCaskill & Kearney, 2016) and was ranked lowest for all param- A grazed perennial pasture requires a sufficient plant population to achieve both production and sustainability goals: high herbage accumulation and persistence (Hayes et al, 2010a,b;McCaskill & Kearney, 2016) by maximizing soil water usage (rooting depth and extraction); having a dry profile in autumn to store winter rain- high ground cover to reduce weeds (Dear, Virgona, Sandral, Swan, & Orchard, 2007;McCaskill & Kearney, 2016), minimize runoff (Murphy, Lodge, & Harden, 2004) and maximize infiltration (Murphy et al, 2010). There is also a threshold plant density, below which a species is not able to achieve these goals (e.g., Dolling, Lyons, & Latta, 2011;Hayes et al, 2010a,b;McCaskill & Kearney, 2016;Virgona, 2003).…”

Section: Discussionmentioning

confidence: 99%

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Optimum plant density of Digitaria eriantha for herbage accumulation and hydrological performance in a summer dominant rainfall zone

Boschma

Murphy

Harden

2019

Grass and Forage Science

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In the frost‐prone, summer dominant rainfall zone of northern NSW and southern Queensland, sown tropical grass pastures commonly establish with plant densities >26 plants per m2, yet the optimum density for maximum herbage accumulation and hydrological performance is not known. A replicated, field study was established in northern NSW in November 2011, using five densities of Digitaria eriantha (digit grass): 0, 1, 4, 9 and 16 plants per m2 and a range of agronomic and hydrologic measures was assessed. The results showed that the largest differences between plant densities in herbage accumulation, root depth, soil water extraction and rainfall refill efficiency occurred during the first 2 years; after this time, digit grass pastures with densities of ≥4 plants per m2 responded similarly. Plant frequency increased with increasing plant density but the treatments did not converge. During the first two growing seasons, there was no effect of plant density on water use efficiency; however, by the third growing season, pastures with 4 plants per m2 were the most water efficient. Overall, the results indicated that 1 plant per m2 was too low to efficiently use resources, 16 plants per m2 utilized the resources quickly then tended to stall, while 4–9 plants per m2 was a good compromise between agronomic and hydrological response, achieving both herbage accumulation and sustainability goals. A practical management advantage of pastures with 4–9 plants per m2 is they allow soil water resources to be available for a longer period of time and potentially provide the opportunity to establish legumes in the ensuing 24‐month period.

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“…Hayes et al. (2010b) also reported little change in SWC below 0.75 m for a range of summer and winter active forage species.…”

Section: Discussionmentioning

confidence: 94%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Optimum plant density of Digitaria eriantha for herbage accumulation and hydrological performance in a summer dominant rainfall zone

Boschma

Murphy

Harden

2019

Grass and Forage Science

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“…The increase in volumetric water content in the pot experiment in the sandy Binnaway Kandosol soil was as much attributable to the additive blend as to the compost, most likely a result of lime being a key ingredient in the additive blend and fertilizer treatments. Lime is known to impact soil water-holding capacity (Roper, 2005; Hayes et al, 2010b), most likely due to changes in soil physical properties that result in reduced dispersion and slaking where lime is applied (Chan et al, 2007). The effect of compost on soil water-holding capacity may have become evident over a longer period of time.…”

Section: Discussionmentioning

confidence: 99%

Addressing biophysical constraints for Australian farmers applying low rates of composted dairy waste to soil

Hayes

McCormick

Oates

et al. 2017

Renew. Agric. Food Syst.

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This study examined the response of forage crops to composted dairy waste (compost) applied at low rates and investigated effects on soil health. The evenness of spreading compost by commercial machinery was also assessed. An experiment was established on a commercial dairy farm with target rates of compost up to 5 t ha −1 applied to a field containing millet [Echinochloa esculenta (A. Braun) H. Scholz] and Pasja leafy turnip (Brassica hybrid). A pot experiment was also conducted to monitor the response of a legume forage crop (vetch; Vicia sativa L.) on three soils with equivalent rates of compost up to 20 t ha −1 with and without 'additive blends' comprising gypsum, lime or other soil treatments. Few significant increases in forage biomass were observed with the application of low rates of compost in either the field or pot experiment. In the field experiment, compost had little impact on crop herbage mineral composition, soil chemical attributes or soil fungal and bacterial biomass. However, small but significant increases were observed in gravimetric water content resulting in up to 22.4 mm of additional plant available water calculated in the surface 0.45 m of soil, 2 years after compost was applied in the field at 6 t ha −1 dried (7.2 t ha −1 undried), compared with the nil control. In the pot experiment, where the soil was homogenized and compost incorporated into the soil prior to sowing, there were significant differences in mineral composition in herbage and in soil. A response in biomass yield to compost was only observed on the sandier and lower fertility soil type, and yields only exceeded that of the conventional fertilizer treatment where rates equivalent to 20 t ha −1 were applied. With few yield responses observed, the justification for applying low rates of compost to forage crops and pastures seems uncertain. Our collective experience from the field and the glasshouse suggests that farmers might increase the response to compost by: (i) increasing compost application rates; (ii) applying it prior to sowing a crop; (iii) incorporating the compost into the soil; (iv) applying only to responsive soil types; (v) growing only responsive crops; and (vi) reducing weed burdens in crops following application. Commercial machinery incorporating a centrifugal twin disc mechanism was shown to deliver double the quantity of compost in the area immediately behind the spreader compared with the edges of the spreading swathe. Spatial variability in the delivery of compost could be reduced but not eliminated by increased overlapping, but this might represent a potential 20% increase in spreading costs.

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Perennial grass and herb options to extend summer–autumn forage in a drought‐prone temperate environment

Stutz,

De Faveri,

Culvenor

2024

Grassland Research

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BackgroundThe ability to finish livestock on pasture over the summer–autumn period could improve the profitability of red meat enterprises in drought‐prone temperate regions. In south‐eastern Australia, traditional perennial options are limited by poor warm‐season performance (phalaris, Phalaris aquatica L.) and widespread environmental constraints (lucerne, Medicago sativa L.). We aimed to identify perennial species suitable for summer–autumn finishing.MethodsWe tested pure swards of summer‐active perennial grasses and herbs (20 cultivars across 14 species) in replicated small‐plot experiments at two sites on the Southern Tablelands of New South Wales, Australia. We assessed early persistence, productivity and warm‐season nutritive characteristics over 2–3 years.ResultsLucerne and chicory (Cichorium intybus L.) persisted well through drought and produced herbage of high quantity and quality through summer–autumn. Digit grass (Digitaria eriantha Steud.) was highly persistent and productive but nutritive values were generally poor. Cocksfoot (Dactylis glomerata L.), tall fescue (Festuca arundinacea Schreb.), perennial ryegrass (Lolium perenne L.), prairie grass (Bromus willdenowii Kunth.) and plantain (Plantago lanceolata L.) were productive but less persistent through drought, while nutritive values were sometimes inadequate.ConclusionsChicory is a good alternative to lucerne, given its excellent summer–autumn performance, ability to survive droughts and superior acid soil tolerance. If appropriate management resolves issues with persistence and nutritive value, several of the other species could also be used to close the warm‐season feed gap in drought‐prone temperate environments.

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Perennial pastures for recharge control in temperate drought-prone environments. Part 2: soil drying capacity of key species

Cited by 17 publications

References 34 publications

Optimum plant density of Digitaria eriantha for herbage accumulation and hydrological performance in a summer dominant rainfall zone

Optimum plant density of Digitaria eriantha for herbage accumulation and hydrological performance in a summer dominant rainfall zone

Addressing biophysical constraints for Australian farmers applying low rates of composted dairy waste to soil

Perennial grass and herb options to extend summer–autumn forage in a drought‐prone temperate environment

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