Register      Login
Crop and Pasture Science Crop and Pasture Science Society
Plant sciences, sustainable farming systems and food quality
RESEARCH ARTICLE

Soil organic carbon and total nitrogen under Leucaena leucocephala pastures in Queensland

Alejandro Radrizzani A B , H. Max Shelton A C , Scott A. Dalzell A and Gunnar Kirchhof A
+ Author Affiliations
- Author Affiliations

A School of Agriculture and Food Sciences, The University of Queensland, St Lucia, Qld 4072, Australia.

B Instituto Nacional de Tecnologia Agropecuaria (INTA), Jujuy 850, 4200, Santiago del Estero, Argentina.

C Corresponding author. Email: m.shelton@uq.edu.au

Crop and Pasture Science 62(4) 337-345 https://doi.org/10.1071/CP10115
Submitted: 1 April 2010  Accepted: 18 March 2011   Published: 19 April 2011

Abstract

Soil organic carbon (OC) and total nitrogen (TN) accumulation in the top 0–0.15 m of leucaena–grass pastures were compared with native pastures and with continuously cropped land. OC and TN levels were highest under long-term leucaena–grass pasture (P < 0.05). For leucaena–grass pastures that had been established for 20, 31, and 38 years, OC accumulated at rates that exceeded those of the adjacent native grass pasture by 267, 140, and 79 kg/ha.year, respectively, while TN accumulated at rates that exceeded those of the native grass pastures by 16.7, 10.8, and 14.0 kg/ha.year, respectively. At a site where 14-year-old leucaena–grass pasture was adjacent to continuously cropped land, there were benefits in OC accumulation of 762 kg/ha.year and in TN accumulation of 61.9 kg/ha.year associated with the establishment of leucaena–grass pastures. Similar C : N ratios (range 12.7–14.5) of soil OC in leucaena and grass-only pastures indicated that plant-available N limited soil OC accumulation in pure grass swards. Higher OC accumulation occurred near leucaena hedgerows than in the middle of the inter-row in most leucaena–grass pastures.

Rates of C sequestration were compared with simple models of greenhouse gas (GHG) emissions from the grazed pastures. The amount of carbon dioxide equivalent (CO2-e) accumulated in additional topsoil OC of leucaena–grass pastures ≤20 years old offset estimates of the amount of CO2-e emitted in methane and nitrous oxide from beef cattle grazing these pastures, thus giving positive GHG balances. Less productive, aging leucaena pastures >20 years old had negative GHG balances; lower additional topsoil OC accumulation rates compared with native grass pastures failed to offset animal emissions.

Additional keywords: carbon balance, carbon sequestration, greenhouse gas balance, permanent pastures, soil organic carbon, soil total nitrogen.


References

Anderson HA, Vaughan D (1985) Soil nitrogen: its extraction, distribution and dynamics. In ‘Soil organic matter and biological activity’. Developments in Plant and Soil Sciences, Vol. 16. (Eds D Vaughan, RE Malcolm) pp. 289–327. (Martinus Nijhoff/Dr W Junk Publishers: Dordrecht, The Netherlands)

Armstrong RD, Kuskopf BJ, Millar G, Whitbread AM, Standley J (1999) Changes in soil chemical and physical properties following legumes and opportunity cropping on a cracking clay soil. Australian Journal of Experimental Agriculture 39, 445–456.
Changes in soil chemical and physical properties following legumes and opportunity cropping on a cracking clay soil.Crossref | GoogleScholarGoogle Scholar |

Bruce RC (1965) Effect of Centrosema pubescens Benth on soil fertility in the humid tropics. Queensland Journal of Agricultural and Animal Sciences 22, 221–226.

Bruce RC, Rayment GE (1982) ‘Analytical methods and interpretations used by the Agricultural Chemistry Branch for soil and land use surveys.’ Queensland Department of Primary Industries Bulletin QB82004. (Queensland Department of Primary Industries: Brisbane)

Burle STM, Shelton HM, Dalzell SA (2003) Nitrogen cycling in degraded Leucaena leucocephala-Brachiaria decumbens pastures on an acid infertile soil in south-east Queensland, Australia. Tropical Grasslands 37, 119–128.

Carter JO, Howden SM, Day KA, McKeon GM (1998) Soil carbon, nitrogen and phosphorus and biodiversity in relation to climate change. In ‘Evaluation of the impact of climate change on northern Australian grazing industries’. Final report for the Rural Industries Research and Development Corporation project DAQ 139A. (Eds GM McKeon, JO Carter, KA Day, WB Hall, SM Howden) pp. 185–249. (RIRDC: Brisbane)

Catchpoole DW, Blair GJ (1990) Forage tree legumes. III. Release of nitrogen from leaf, faeces and urine derived from leucaena and gliricidia leaf. Australian Journal of Agricultural Research 41, 539–547.
Forage tree legumes. III. Release of nitrogen from leaf, faeces and urine derived from leucaena and gliricidia leaf.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK3MXitlSjuw%3D%3D&md5=e304ff559a10c189ae07b271849fcfcdCAS |

Clark H, Pinares-Patino C, deKlein C (2005) Methane and nitrous oxide emissions from grazed grasslands. In ‘Grassland: a global resource’. (Ed. DA McGilloway) pp. 279–293. (Wageningen Academic Publishers: Wageningen, The Netherlands)

Cooksley DG, Prinsen JH, Paton CJ (1988) Leucaena leucocephala production in subcoastal, south-east Queensland. Tropical Grasslands 22, 21–26.

Cullen BR, Hill JO (2006) A survey of the use of lucerne, butterfly pea and lablab in ley pastures in the mixed-farming systems of northern Australia. Tropical Grasslands 40, 24–32.

Dalal RC, Carter JO (2000) Soil organic matter dynamics and carbon sequestration in Australian tropical soils. In ‘Global climate change and tropical ecosystems’. (Eds R Lal, JM Kimble, BA Stewart) pp. 283–314. (CRC Press: Boca Raton, FL)

Dalal RC, Mayer RJ (1986) Long-term trends in fertility of soils under continuous cultivation and cereal cropping in southern Queensland. II. Total organic carbon and its rate of loss from the soil profile. Australian Journal of Soil Research 24, 265–279.
Long-term trends in fertility of soils under continuous cultivation and cereal cropping in southern Queensland. II. Total organic carbon and its rate of loss from the soil profile.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaL28XkvFKmsL8%3D&md5=42aa65d50432cb4ebda99175a8a89f48CAS |

Dalal RC, Strong WM, Weston EJ, Cooper JE, Lehane KJ, King AJ, Chicken CJ (1995) Sustaining productivity of a vertisol at Warra, Queensland, with fertilisers, no-tillage, or legumes. 1. Organic matter status. Australian Journal of Experimental Agriculture 35, 903–913.
Sustaining productivity of a vertisol at Warra, Queensland, with fertilisers, no-tillage, or legumes. 1. Organic matter status.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK28Xhs1yiu7c%3D&md5=a10de4cf587b39c914e44e657a93e91cCAS |

Dalzell SA, Shelton HM (2002) Genotypic variation in proanthocyanadin status in the Leucaena genus. The Journal of Agricultural Science 138, 209–220.
Genotypic variation in proanthocyanadin status in the Leucaena genus.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38Xjs12jtLk%3D&md5=7223e800f07b65bcd4a7821e0ee8cc51CAS |

Department of Climate Change and Energy Efficiency (2010) ‘National greenhouse gas inventory 2008: accounting for the Kyoto target.’ (Department of Climate Change and Energy Efficiency: Canberra)

Emerson WW (1994) Aggregate slaking and dispersion class, bulk properties of soil. Australian Journal of Soil Research 32, 173–184.
Aggregate slaking and dispersion class, bulk properties of soil.Crossref | GoogleScholarGoogle Scholar |

Fisher MJ, Rao IM, Ayarza MA, Lascano CE, Sanz JI, Thomas RJ, Vera RR (1994) Carbon storage by introduced deep-rooted grasses in the South American savannas. Nature 371, 236–238.
Carbon storage by introduced deep-rooted grasses in the South American savannas.Crossref | GoogleScholarGoogle Scholar |

Follett RF, Leavitt SW, Kimble JM, Pruessner EG (2003) Paleoenvironmental inferences from δ13C of soil organic C in 14C-dated profiles in the U.S. Great Plains. In ‘XVI INQUA Congress’. Reno, Nevada, 23–30 July 2003. Program with abstracts. p. 204. (Desert Research Institute: Reno, NV)

Fownes JH, Anderson DG (1991) Changes in nodule and root biomass of Sesbania sesban and Leucaena leucocephala following coppicing. Plant and Soil 138, 9–16.
Changes in nodule and root biomass of Sesbania sesban and Leucaena leucocephala following coppicing.Crossref | GoogleScholarGoogle Scholar |

Garcia GW, Ferguson TU, Neckles FA, Archibald KAE (1996) The nutritive value and forage productivity of Leucaena leucocephala. Animal Feed Science and Technology 60, 29–41.
The nutritive value and forage productivity of Leucaena leucocephala.Crossref | GoogleScholarGoogle Scholar |

Gillespie RL, Shields PG, Cannon RS (1991) ‘Land management manual Dawson–Callide district.’ (Queensland Department of Primary Industries: Brisbane)

Graham TWG, Webb AA, Waring SA (1981) Soil-nitrogen status and pasture productivity after clearing of brigalow (Acacia harpophylla). Australian Journal of Experimental Agriculture and Animal Husbandry 21, 109–118.

Hossain SA, Dalal RC, Waring SA, Strong WM, Weston EJ (1996) Comparison of legume-based cropping systems at Warra, Queensland. I. Soil nitrogen and organic carbon accretion and potentially mineralisable nitrogen. Australian Journal of Soil Research 34, 273–287.
Comparison of legume-based cropping systems at Warra, Queensland. I. Soil nitrogen and organic carbon accretion and potentially mineralisable nitrogen.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK28XisV2is78%3D&md5=9fb44b89dcfea37fb0ea976445ab2161CAS |

IPCC (2006) 2006 IPCC guidelines for national greenhouse inventories. In ‘National Greenhouse Inventories Programme’. (Eds HS Eggleston, L Buendia, K Miwa, T Ngara, K Tanabe) (Institute for Global Environmental Strategies: Hayama, Japan)

Irvine SA, Reid DJ (2001) Field prediction of sodicity in dryland agriculture in Central Queensland, Australia. Australian Journal of Soil Research 39, 1349–1357.
Field prediction of sodicity in dryland agriculture in Central Queensland, Australia.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38Xmt1eitro%3D&md5=ab2998087742922dbee215e17ec2080eCAS |

Isbell RF (1962) ‘Soils and vegetation of the brigalow lands, eastern Australia.’ Soils and Land Use Series 43. (CSIRO Division of Soils: Melbourne)

Isbell RF (1996) ‘The Australian Soil Classification.’ (CSIRO Publishing: Melbourne)

Jayasundara HPS, Dennett MD, Sangakkara UR (1997) Biological nitrogen fixation in Gliricidia sepium and Leucaena leucocephala and transfer of fixed nitrogen to an associated grass. Tropical Grasslands 31, 529–537.

Jha MN, Dimri BM, Gupta MK (1991) Soil nutrient changes in Leucaena leucocephala plantings of different durations. Leucaena Research Reports 12, 42–44.

Kang BT, Grimme H, Lawson TL (1985) Alley cropping sequentially cropped maize and cowpea with leucaena on a sandy soil in southern Nigeria. Plant and Soil 85, 267–277.
Alley cropping sequentially cropped maize and cowpea with leucaena on a sandy soil in southern Nigeria.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaL2MXksFehsb0%3D&md5=6556fd2d69a5cf6243db92a03145b56cCAS |

Lalljee B, Facknath S, Osman AM (1998) Improvement of soil properties under long-term Leucaena leucocephala. In ‘Leucaena – adaptation, quality and farming systems. Proceedings of a Workshop’. Hanoi, Vietnam, 9–14 February 1998. ACIAR Proceedings No. 86. (Eds HM Shelton, RC Gutteridge, BF Mullen, RA Bray) pp. 178–180. (ACIAR: Canberra)

’t Mannetje L. (2007) The role of grasslands and forests as carbon stores. Tropical Grasslands 41, 50–54.

McDonald RC, Isbell RF, Speight JG, Walker J, Hopkins MS (1990) ‘Australian soil and land survey: field handbook.’ (CSIRO Land and Water: Canberra)

McIntyre DS, Barrow KJ (1972) An improved sampling method for small undisturbed cores. Soil Science 114, 239–241.
An improved sampling method for small undisturbed cores.Crossref | GoogleScholarGoogle Scholar |

MLA (2006) ‘Beef cattle nutrition: an introduction to the essentials.’ (Meat and Livestock Australia Ltd: Sydney)

Myers RJK, Robbins GB (1991) Sustaining productive pastures in the tropics. 5. Maintaining productive sown grass pastures. Tropical Grasslands 25, 104–110.

Northcote KH, Hubble GD, Isbell RF, Thompson CH, Bettenay E (1975) ‘A description of Australian soils.’ (CSIRO Publishing: Melbourne)

Onim JFM, Mathura M, Otieno K, Fitzhugh HA (1990) Soil fertility changes and response of maize and beans to green manures of leucaena, sesbania and pigeonpea. Agroforestry Systems 12, 197–215.
Soil fertility changes and response of maize and beans to green manures of leucaena, sesbania and pigeonpea.Crossref | GoogleScholarGoogle Scholar |

Radrizzani A, Shelton HM, Dalzell SA (2010) Response of Leucaena leucocephala pastures to phosphorus and sulfur application in Queensland. Animal Production Science 50, 961–975.
Response of Leucaena leucocephala pastures to phosphorus and sulfur application in Queensland.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXhtlWmtLfM&md5=0895cb9f25fdb4ad6f1dc720612112aaCAS |

Rayment GE, Higginson FR (1992) ‘Australian laboratory handbook of soil and water chemical methods.’ (Inkata Press: Melbourne)

Reid RE, Sorby P, Baker DE (1986) ‘Soils of the Brian Pastures Research Station, Gayndah, Queensland.’ (Queensland Department of Primary Industries: Brisbane)

Robertson FA, Myers RJK, Saffigna PG (1997) Nitrogen cycling in brigalow clay soils under pasture and cropping. Australian Journal of Soil Research 35, 1323–1339.
Nitrogen cycling in brigalow clay soils under pasture and cropping.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2sXnsVehtr8%3D&md5=e2b60541a249fb5d56119777022d5704CAS |

Shaw RJ, Yule DF (1978) ‘The assessment of soils for irrigation, Emerald, Queensland.’ Agricultural Chemistry Branch Technical Report 13. (Queensland Department of Primary Industries: Brisbane)

Shelton M, Dalzell S (2007) Production, economic and environmental benefits of leucaena pastures. Tropical Grasslands 41, 174–190.

Spain AV, Isbell RF, Probert ME (1983) Soil organic matter. In ‘Soils: an Australian viewpoint’. pp. 551–563. (Academic Press: London)

Standley J, Hunter HM, Thomas GA, Blight GW, Webb AA (1990) Tillage and crop residue management affect Vertisol properties and grain sorghum growth over seven years in the semi-arid sub-tropics. 2. Changes in soil properties. Soil & Tillage Research 18, 367–388.
Tillage and crop residue management affect Vertisol properties and grain sorghum growth over seven years in the semi-arid sub-tropics. 2. Changes in soil properties.Crossref | GoogleScholarGoogle Scholar |

Tarré R, Macedo R, Cantarutti RB, Rezende C de P, Pereira JM, Ferreira E, Alves BJR, Urquiaga S, Boddey RM (2001) The effect of the presence of a forage legume on nitrogen and carbon levels in soils under Brachiaria pastures in the Atlantic forest region of the South of Bahia, Brazil. Plant and Soil 234, 15–26.
The effect of the presence of a forage legume on nitrogen and carbon levels in soils under Brachiaria pastures in the Atlantic forest region of the South of Bahia, Brazil.Crossref | GoogleScholarGoogle Scholar |

Whitehouse MJ, Littler JW (1984) Effect of pasture on subsequent wheat crops on a black earth soil of the Darling Downs. II. Organic C, nitrogen and pH changes. Queensland Journal of Agricultural and Animal Sciences 41, 13–20.