Register      Login
Animal Production Science Animal Production Science Society
Food, fibre and pharmaceuticals from animals
RESEARCH ARTICLE (Open Access)

The effects of pasture inputs and intensive rotational grazing on superfine wool production, quality and income

D. Cottle A , C. A. Gaden B , J. Hoad A , D. Lance C , J. Smith D and J. M. Scott A E
+ Author Affiliations
- Author Affiliations

A School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia.

B ‘Beaumont’, Invergowrie, NSW 2350, Australia.

C ‘Cressbrook’, Enmore Road, Armidale, NSW 2350, Australia.

D CSIRO Livestock Industries, Armidale, NSW 2350, Australia.

E Corresponding author. Email: dr.jimscott@gmail.com

Animal Production Science 53(8) 750-764 https://doi.org/10.1071/AN12289
Submitted: 16 August 2012  Accepted: 13 February 2013   Published: 10 July 2013

Journal Compilation © CSIRO Publishing 2013 Open Access CC BY-NC-ND

Abstract

A farmlet experiment was conducted between July 2000 and December 2006 as part of the Cicerone Project, which sought to enhance the profitability and sustainability of grazing enterprises on the Northern Tablelands of New South Wales, Australia. A self-replacing Merino enterprise was grazed as the dominant livestock enterprise, together with ~20% of the carrying capacity as cattle, on each of three farmlet treatments: higher levels of soil fertility and pasture renovation with flexible rotational grazing over eight paddocks (farmlet A), moderate soil fertility and pasture renovation with flexible rotational grazing over eight paddocks (farmlet B) and moderate soil fertility and pasture renovation with intensive rotational grazing over 37 paddocks (farmlet C). Prior to commencement of the trial, the three 53-ha farmlets were allocated equivalent areas of land based on soil type, slope and recent fertiliser history.

This paper describes the effects of the three pasture and grazing management strategies on the production, quality and value of the wool produced per head, per ha and per farmlet. Up until 2001 there were no differences in wool production between farmlets. Thereafter, significant differences between farmlets emerged in greasy fleece weight per head and price received per kg of fleece wool. For example, the clean fleece value averaged over the 2003–05 shearings for all hoggets, ewes and wethers was 1531, 1584 and 1713 cents/kg for farmlets A, B and C, respectively.

There were small but significant differences, which varied between sheep class and year, between the farmlets in average fibre diameter and staple length but less so with staple strength. In general, while the differences between farmlets in staple strength varied over time, farmlets A and B tended to have wool with longer staple length and broader fibre diameter than farmlet C and this affected wool value per kg.

Differences in wool income per ha between farmlets grew in later years as the farmlet treatments took effect. In spite of farmlet A having a slightly lower wool value per kg, after taking into account its greater fleece weight per head and its higher stocking rate, the total wool income per ha was higher than on either farmlets B or C. The average gross wool income per ha from 2003 to 2005 was $303, $215 and $180 for farmlets A, B and C, respectively. The highest amount of greasy wool produced was in 2004 when 38.2, 26.5 and 21.5 kg/ha was harvested from farmlets A, B and C, respectively.

The fibre diameter profiles of 2-year-old ewes showed similar profiles for farmlets A and B but a significantly finer fibre diameter profile for farmlet C ewes due to intensive rotational grazing. However, sheep on all three farmlets produced wool with high staple strength.

Multivariate analyses revealed that greasy fleece weight, staple length and staple strength were significantly positively correlated with the proportion of the farm grazed at any one time, and with soil phosphorus, legume herbage and green digestible herbage thus highlighting the significant influence of pasture and soil inputs and of grazing management on wool production and quality.

Additional keywords: cell grazing, farming systems, fibre diameter profiles.


References

Adams NR, Cronje PB (2003) A review of the biology linking fibre diameter with fleece weight, live weight, and reproduction in Merino sheep. Australian Journal of Agricultural Research 54, 1–10.
A review of the biology linking fibre diameter with fleece weight, live weight, and reproduction in Merino sheep.Crossref | GoogleScholarGoogle Scholar |

Adams NR, Oldham CM (1998) Constraints to productivity imposed by our capacity to manage hauteur. In ‘Animal production in Australia. Armidale, NSW’. pp. 101–103. (Australian Society of Animal Production) Available at http://livestocklibrary.com.au/bitstream/handle/1234/8986/Ward98.PDF?sequence=1 [Verified 3 March 2013]

Alford AR, Griffith GR, Davies BL (2003) ‘Livestock farming systems in the Northern Tablelands of NSW: an economic analysis.’ (NSW Agriculture: Orange) Available at http://www.dpi.nsw.gov.au/__data/assets/pdf_file/0004/146551/err-12-Livestock-Farming-Systems-in-the-Northern-Tablelands-of-NSW.pdf [Verified 3 March 2013]

Anon. (2011a) ‘LANDSCAN – PROfarm course.’ (NSW Department of Primary Industries) Available at http://www.dpi.nsw.gov.au/agriculture/profarm/courses/landscan [Verified 3 March 2013]

Anon. (2011b) ‘Woolcheque.’ (Australian Wool Innovation Ltd) Available at http://203.94.169.100/WoolCheque/Public/BlankWorksheet.aspx [Verified 3 March 2013]

Badgery WB, Cranney P, Millar GD, Mitchell D, Behrendt K (2012) Intensive rotational grazing can improve profitability and environmental outcomes. In ‘Proceedings of the 27th annual conference of the Grassland Society of NSW Inc. Wagga Wagga’. (Eds C Harris, G Lodge, C Waters) pp. 85–91. (The Grassland Society of NSW: Orange)

Behrendt K, Scott JM, Mackay DF, Murison R (2013) Comparing the climate experienced during the Cicerone farmlet experiment against the climatic record. Animal Production Science 53, 658–669.
Comparing the climate experienced during the Cicerone farmlet experiment against the climatic record.Crossref | GoogleScholarGoogle Scholar |

Bell AK, Allan CJ (2000) PROGRAZE – an extension package in grazing and pasture management. Australian Journal of Experimental Agriculture 40, 325–330.
PROGRAZE – an extension package in grazing and pasture management.Crossref | GoogleScholarGoogle Scholar |

Brims MA, Peterson AD, Gherardi SG (1999) ‘Introducing the OFDA2000 – for rapid measurement of diameter profile on greasy wool staples.’ (International Wool Textile Organisation: Florence, Italy)

Briske DD, Sayre NF, Huntsinger L, Fernandez-Gimenez M, Budd B, Derner JD (2011) Origin, persistence, and resolution of the rotational grazing debate: integrating human dimensions into rangeland research. Rangeland Ecology and Management 64, 325–334.
Origin, persistence, and resolution of the rotational grazing debate: integrating human dimensions into rangeland research.Crossref | GoogleScholarGoogle Scholar |

Brown DJ, Crook BJ (2005) Environmental responsiveness of fibre diameter in grazing fine wool Merino sheep. Australian Journal of Agricultural Research 56, 673–684.
Environmental responsiveness of fibre diameter in grazing fine wool Merino sheep.Crossref | GoogleScholarGoogle Scholar |

Brown DJ, Schlink AC (2002) A comparison of fibre diameter profiles generated using 2-mm Snippit techniques to those measured using the OFDA2000. Wool Technology and Sheep Breeding 50, 27–39.

Brown DJ, Crook BJ, Purvis IW (2000a) The estimation of fibre diameter profile characteristics using reduced profiling techniques. Wool Technology and Sheep Breeding 48, 1–14.

Brown DJ, Crook BJ, Purvis IW (2000b) Variation in fibre diameter profile characteristics between wool staple in Merino sheep. Wool Technology and Sheep Breeding 48, 86–93.

Brown DJ, Crook BJ, Purvis IW (2002) Differences in fibre diameter profile characteristics in wool staples from Merino sheep and their relationship with staple strength between years, environments and bloodlines. Australian Journal of Agricultural Research 53, 481–491.
Differences in fibre diameter profile characteristics in wool staples from Merino sheep and their relationship with staple strength between years, environments and bloodlines.Crossref | GoogleScholarGoogle Scholar |

Carter E, Day H (1970) Interrelationships of stocking rate and superphosphate rate on pasture as determinants of animal production. I. Continuously grazed old pasture land. Australian Journal of Agricultural Research 21, 473–491.
Interrelationships of stocking rate and superphosphate rate on pasture as determinants of animal production. I. Continuously grazed old pasture land.Crossref | GoogleScholarGoogle Scholar |

Cayley JWD, Saul GR, McCaskill MR (2002) High-fertility pastures in south-west Victoria can be economically and environmentally sustainable. Wool Technology and Sheep Breeding 50, 724–729.

Chapman DF, McCaskill MR, Quigley PE, Thompson AN, Graham JF, Borg D, Lamb J, Kearney G, Saul GR, Clark SG (2003) Effects of grazing method and fertiliser inputs on the productivity and sustainability of phalaris-based pastures in Western Victoria. Australian Journal of Experimental Agriculture 43, 785–798.
Effects of grazing method and fertiliser inputs on the productivity and sustainability of phalaris-based pastures in Western Victoria.Crossref | GoogleScholarGoogle Scholar |

Cottle DJ (2010) Wool preparation, testing and marketing. In ‘International sheep and wool handbook’. (Ed. DJ Cottle) pp. 581–618. (AWI: Sydney)

Curll M (1977) Superphosphate on perennial pastures. I. Effects of a pasture response on sheep production. Australian Journal of Agricultural Research 28, 991–1005.
Superphosphate on perennial pastures. I. Effects of a pasture response on sheep production.Crossref | GoogleScholarGoogle Scholar |

Gloag C, Behrendt R (2002) The influence of measurement interval and grease on OFDA2000 profile characteristics. Wool Technology and Sheep Breeding 50, 805–811.

Gloag C, Kearney G, Behrendt R (2004) Monitoring monthly changes in fibre diameter with the OFDA2000. Animal Production in Australia 25, 249. Available at http://www.publish.csiro.au/?act=view_file&file_id=SA0401094.pdf [Verified 13 March 2013]

Graham JF, Cullen BR, Lodge GM, Andrew MH, Christy BP, Holst PJ, Wang X, Murphy SR, Thompson AN (2003) SGS Animal Production Theme: effect of grazing system on animal productivity and sustainability across southern Australia. Australian Journal of Experimental Agriculture 43, 977–991.
SGS Animal Production Theme: effect of grazing system on animal productivity and sustainability across southern Australia.Crossref | GoogleScholarGoogle Scholar |

Guppy CN, Edwards C, Blair GJ, Scott JM (2013) Whole-farm management of soil nutrients drives productive grazing systems: the Cicerone farmlet experiment confirms earlier research. Animal Production Science 53, 649–657.
Whole-farm management of soil nutrients drives productive grazing systems: the Cicerone farmlet experiment confirms earlier research.Crossref | GoogleScholarGoogle Scholar |

Hamilton BA (1975) Factors determining the productivity of sheep grazing four temperate perennial grasses. PhD thesis, University of New England, Armidale.

Hansford KA (1997) Wool strength and topmaking. Wool Technology and Sheep Breeding 45, 309–320.

Hansford KA (Ed.) (2004) ‘Fibre diameter profile. Proceedings of workshop held at CSIRO Livestock Industires ‘Chiswick’, Armidale, October 2004.’ (Sheep CRC: Armidale, NSW)

Hansford KA, Kennedy JP (1988) The relationship between variation in fibre diameter along staples and staple strength. In ‘8th International Wool Textile Research Conference. Christchurch, New Zealand’. (Ed. G Cranshaw) pp. 590–598. (WRONZ: Christchurch)

Hinch GN, Hoad J, Lollback M, Hatcher S, Marchant R, Colvin A, Scott JM, Mackay D (2013a) Livestock weights in response to three whole-farmlet management systems. Animal Production Science 53, 727–739.
Livestock weights in response to three whole-farmlet management systems.Crossref | GoogleScholarGoogle Scholar |

Hinch GN, Lollback M, Hatcher S, Hoad J, Marchant R, Mackay DF, Scott JM (2013b) Effects of three whole-farmlet management systems on Merino ewe fat scores and reproduction. Animal Production Science 53, 740–749.
Effects of three whole-farmlet management systems on Merino ewe fat scores and reproduction.Crossref | GoogleScholarGoogle Scholar |

Jackson N, Downes A (1979) The fibre diameter profile of wool staples from individual sheep. Australian Journal of Agricultural Research 30, 163–171.
The fibre diameter profile of wool staples from individual sheep.Crossref | GoogleScholarGoogle Scholar |

Kaine G, Doyle B, Sutherland H, Scott JM (2013) Surveying the management practices and research needs of graziers in the New England region of New South Wales. Animal Production Science 53, 602–609.
Surveying the management practices and research needs of graziers in the New England region of New South Wales.Crossref | GoogleScholarGoogle Scholar |

Lodge GM, Murphy SR, Harden S (2003) Effects of grazing and management on herbage mass, persistence, animal production and soil water content of native pastures. 1. A redgrass-wallaby grass pasture, Barraba, North West Slopes, New South Wales. Australian Journal of Experimental Agriculture 43, 875–890.
Effects of grazing and management on herbage mass, persistence, animal production and soil water content of native pastures. 1. A redgrass-wallaby grass pasture, Barraba, North West Slopes, New South Wales.Crossref | GoogleScholarGoogle Scholar |

Marler JW, Hansford KA, McLachlan IM (2002) The precision of OFDA2000 and Fleecescan for estimating the diameter characteristics of fleeces: a case study. Wool Technology and Sheep Breeding 50, 832–839.

Mason WK, Lodge GM, Allan CJ, Andrew MH, Johnson T, Russell B, Simpson IH (2003) An appraisal of Sustainable Grazing Systems: the program, the triple bottom line impacts and the sustainability of grazing systems. Australian Journal of Experimental Agriculture 43, 1061–1082.
An appraisal of Sustainable Grazing Systems: the program, the triple bottom line impacts and the sustainability of grazing systems.Crossref | GoogleScholarGoogle Scholar |

Masters DG, Mata G, Liu SM, Schlink AC (2002) Frequence of feeding lupin and canola meal supplements to young sheep influences wool growth and mitotic rate but not staple strength. Australian Journal of Agricultural Research 42, 103–109.

McCosker T (2000) Cell grazing – the first 10 years in Australia. Tropical Grasslands 34, 207–218.

Morley FHW (1981) Management of grazing systems. In ‘Grazing animals’. (Ed. FHW Morley) pp. 379–400. (Elsevier: Amsterdam)

Murison R, Scott JM (2013) Statistical methodologies for drawing causal inference from an unreplicated farmlet experiment conducted by the Cicerone Project. Animal Production Science 53, 643–648.
Statistical methodologies for drawing causal inference from an unreplicated farmlet experiment conducted by the Cicerone Project.Crossref | GoogleScholarGoogle Scholar |

Norton BE (1998) The application of grazing management to increase sustainable livestock production. In ‘Animal production in Australia’. Armidale, NSW. (Eds JL Corbett, PJ Vickery) Available at http://www.asap.asn.au/livestocklibrary/1998/MCCMONT.PDF [Verified 3 March 2013]

Peterson AD, Gherardi SG (2001) The ability of the OFDA2000 to measure fleeces and sale lots on farm. Wool Technology and Sheep Breeding 49, 110

Pratley JE, Virgona JM (2010) Pasture management. In ‘International sheep and wool handbook’. (Ed. DJ Cottle) pp. 425–444. (Nottingham University Press: Nottingham)

R Development Core Team (2011) ‘R: a language and environment for statistical computing.’ (R Foundation for Statistical Computing: Vienna) Available at http://www.R-project.org [Verified 3 March 2013]

Robertson SM, Robards GE, Wolfe EC (2000) Grazing management of reproducing ewes affects staple strength. Australian Journal of Experimental Agriculture 40, 783–794.
Grazing management of reproducing ewes affects staple strength.Crossref | GoogleScholarGoogle Scholar |

Ryan M (2006) The implicit market for characteristics of Merino wool: an hedonic approach. Bachelor of Agricultural Economics thesis, University of Sydney.

Saul GR, Chapman DF (2002) Grazing methods, productivity and sustainability for sheep and beef pastures in temperate Australia. Wool Technology and Sheep Breeding 50, 449–464.

Saul G, Kearney G, Borg D (2011) Pasture systems to improve productivity of sheep in south-western Victoria 2. Animal production from ewes and lambs. Animal Production Science 51, 982–989.
Pasture systems to improve productivity of sheep in south-western Victoria 2. Animal production from ewes and lambs.Crossref | GoogleScholarGoogle Scholar |

Scott JF, Scott JM, Cacho OJ (2013a) Whole-farm returns show true profitability of three different livestock management systems. Animal Production Science 53, 780–787.
Whole-farm returns show true profitability of three different livestock management systems.Crossref | GoogleScholarGoogle Scholar |

Scott JM, Gaden CA, Edwards C, Paull DR, Marchant R, Hoad J, Sutherland H, Coventry T, Dutton P (2013b) Selection of experimental treatments, methods used and evolution of management guidelines for comparing and measuring three grazed farmlet systems. Animal Production Science 53, 628–642.
Selection of experimental treatments, methods used and evolution of management guidelines for comparing and measuring three grazed farmlet systems.Crossref | GoogleScholarGoogle Scholar |

Scott JM, Munro M, Rollings N, Browne W, Vickery PJ, Macgregor C, Donald GE, Sutherland H (2013c) Planning for whole-farm systems research at a credible scale: subdividing land into farmlets with equivalent initial conditions. Animal Production Science 53, 618–627.
Planning for whole-farm systems research at a credible scale: subdividing land into farmlets with equivalent initial conditions.Crossref | GoogleScholarGoogle Scholar |

Shakhane LM, Mulcahy C, Scott JM, Hinch GN, Donald GE, Mackay DF (2013a) Pasture herbage mass, quality and growth in response to three whole-farmlet management systems. Animal Production Science 53, 685–698.
Pasture herbage mass, quality and growth in response to three whole-farmlet management systems.Crossref | GoogleScholarGoogle Scholar |

Shakhane LM, Scott JM, Murison R, Mulcahy C, Hinch GN, Morrow A, Mackay DF (2013b) Changes in botanical composition on three farmlets subjected to different pasture and grazing management strategies. Animal Production Science 53, 670–684.
Changes in botanical composition on three farmlets subjected to different pasture and grazing management strategies.Crossref | GoogleScholarGoogle Scholar |

Smith JL, Purvis IW, Lee GJ (2006) Fibre diameter profiles – potential applications for improving fine-wool quality. International Journal of Sheep and Wool Science 54, 170–177.

Sutherland H, Scott JM, Gray GD, Woolaston RR (2013) Creating the Cicerone Project: seeking closer engagement between livestock producers, research and extension. Animal Production Science 53, 593–601.
Creating the Cicerone Project: seeking closer engagement between livestock producers, research and extension.Crossref | GoogleScholarGoogle Scholar |

Thompson AN, Hynd PI (1998) Wool growth and fibre diameter changes in young Merino sheep genetically different in staple strength and fed different levels of nutrition. Australian Journal of Agricultural Research 49, 889–898.
Wool growth and fibre diameter changes in young Merino sheep genetically different in staple strength and fed different levels of nutrition.Crossref | GoogleScholarGoogle Scholar |

Thompson AN, Ferguson MB, Gordon DJ, Kearney GA, Oldham CM, Paganoni BL (2011) Improving the nutrition of Merino ewes during pregnancy increases the fleece weight and reduces the fibre diameter of their progeny’s wool during their lifetime and these effects can be predicted from the ewe’s liveweight profile. Animal Production Science 51, 794–804.
Improving the nutrition of Merino ewes during pregnancy increases the fleece weight and reduces the fibre diameter of their progeny’s wool during their lifetime and these effects can be predicted from the ewe’s liveweight profile.Crossref | GoogleScholarGoogle Scholar |

Walkden-Brown SW, Colvin AF, Hall E, Knox MR, Mackay DF, Scott JM (2013) Grazing systems and worm control in sheep: a long-term case study involving three management systems with analysis of factors influencing faecal worm egg count. Animal Production Science 53, 765–779.
Grazing systems and worm control in sheep: a long-term case study involving three management systems with analysis of factors influencing faecal worm egg count.Crossref | GoogleScholarGoogle Scholar |

Warn LK, Frame HR, McLarty GR (2002) Effects of grazing method and soil fertility on stocking rate and wool production. Wool Technology and Sheep Breeding 50, 510–517.

Whalley R, Robinson G, Taylor J (1976) General effects of management and grazing by domestic livestock on the rangelands of the Northern Tablelands of New South Wales. The Rangeland Journal 1, 174–190.
General effects of management and grazing by domestic livestock on the rangelands of the Northern Tablelands of New South Wales.Crossref | GoogleScholarGoogle Scholar |

Willoughby W (1959) Limitations to animal production imposed by seasonal fluctuations in pasture and by management procedures. Australian Journal of Agricultural Research 10, 248–268.
Limitations to animal production imposed by seasonal fluctuations in pasture and by management procedures.Crossref | GoogleScholarGoogle Scholar |

Zuur AF, Ieno EN, Smith GM (2007) ‘Analysing ecological data.’ (Springer: New York)