Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
The Rangeland Journal The Rangeland Journal Society
Journal of the Australian Rangeland Society
Shopping Cart: ( empty )
You are here: Home > Journals > RJ > RJ21051
RESEARCH ARTICLE (Open Access)
Contents Vol 45(6)

Above-ground carbon in mulga-dominated rangelands, Murchison Bioregion, Western Australia

Adrian Williams A * , Peter Russell B and David Blood C
+ Author Affiliations
- Author Affiliations

A Williams Ag-Environmental Consulting, PO Box 841, Bridgetown, WA 6255, Australia.

B PO Box 523, Margaret River, WA 6285, Australia.

C Coodawa Contracting, 32, Galilee Way, Woorree, Geraldton, WA 6530, Australia.

* Correspondence to: awilliams@pendragondryland.com.au

The Rangeland Journal 45(6) 211-223 https://doi.org/10.1071/RJ21051
Submitted: 14 February 2023  Accepted: 13 May 2024  Published: 30 May 2024

© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing on behalf of the Australian Rangeland Society. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

The paper reports outcomes of surveys conducted between 2012 and 2014 in mulga (Acacia aneura) dominated arid rangelands of the Murchison Bioregion of Western Australia, approximately 470 km north-east of Perth, the State capital. The bioregion covers 281,200 km2. The purpose of the surveys was to measure the stocks of above-ground biomass (AGB) and sequestered organic carbon within 140 plots, each 25 m × 25 m. The resulting large database was interrogated to (1) find a relationship between AGB and contained carbon in trees and in shrubs, and (2) find plant metrics to predict AGB. At the plant level, analysis confirmed the finding that tree AGB was composed of a mean 47% carbon, with shrub AGB averaging 46%. This allowed biomass to be used as a surrogate for carbon in our further analysis. Tree canopy area was found to provide the best linear relationship with tree and shrub AGB. The linear relationships held true for individual plants across the survey sites and across the land systems involved. At the plot level, measures of AGB and carbon stocks varied across land systems. Because tree canopy can be measured by remote-sensing, the results of these field-only surveys indicated a potential for AGB and carbon in mulga-dominated rangelands to be assessed remotely.

Keywords: carbon estimation through remote sensing, carbon percentage of biomass, mulga rangelands, Murchison Bioregion, plant morphological metrics, total above ground biomass, tree and shrub biomass estimation, Western Australia.

References

Adams M, Grierson P, Bussau A, Dorling K (2001) Biomass and carbon in vegetation of the Pilbara region, Western Australia. Final report submitted to Hamersley Iron, BHP and Robe. Ecosystem Research Group, UWA, Perth.

Baumber A, Waters C, Cross R, Metternicht G, Simpson M (2020) Carbon farming for resilient rangelands: people, paddocks and policy. The Rangeland Journal 42, 293-307.
| Crossref | Google Scholar |

Bureau of Meteorology, Government of Australia (2023) BOM – Summary statistics MOUNT MAGNET. Available at http://www.bom.gov.au/climate/averages/tables/cw_007057.shtml [last updated 30 November 2010]

Canfield RH (1941) Application of the line interception method in sampling range vegetation. Journal of Forestry 39(4),.
| Google Scholar | PubMed |

Carbon Market Institute (2021) Blueprint for holistic approach to carbon farming. (Active Land Management & Agricultural Production (AL-MAP) Method). Available at https://carbonmarketinstitute.org/app/uploads/2021/08/AL-MAP-Method-Blueprint_final.pdf

Carbon Market Institute (2023) May 2023 update. Available at https://mailchi.mp/carbonmarketinstitute/critical-reforms-headline-busy-start-to-320734?e=eef365588a

Christian CS, Stewart GA (1946) General Report on Survey of Katherine-Darwin Region, Compiled in collaboration with L. C. Noakes and S. T. Blake. CSIRO Land Research Series No. 1, 1946. Available at https://hdl.handle.net/10070/674247

Curry PJ, Payne AL, Leighton KA, Hennig P, Blood DA (1994) ‘An inventory and condition survey of the Murchison River Catchment.’ Technical Bulletin No. 84. (Western Australian Department of Agriculture: Perth, WA, Australia)

De Gruijter J, Brus D, Bierkens M, Knotters M (2005) ‘Sampling for Natural Resource Monitoring.’ (Springer-Verlag: Heidelberg, Germany) ISBN 540-22486-6.

Department of Climate Change, Energy, the Environment and Water (2023) Independent Review of Australian Carbon Credit Units. Available at https://www.dcceew.gov.au/climate-change/emissions-reduction/independent-review-accus

Department of Climate Change, Energy, the Environment and Water (n.d.) Murchison Bioregion. Available at https://www.dcceew.gov.au/sites/default/files/env/resources/a8015c25-4aa2-4833-ad9c-e98d09e2ab52/files/bioregion-murchison.pdf

Department of Industry, Science, Energy and Resources (DISER) (2020) FullCAM Guidelines: requirements for using the Full Carbon Accounting Model (FullCAM) in the Emissions Reduction Fund (ERF) methodology determination Carbon Credits (Carbon Farming Initiative) (Human Induced Regeneration of a Permanent Even Aged Native Forest—1.1) Methodology Determination 2013, Version 3.0, 2020. Available at https://cer.gov.au/2020-fullcam-now-available

Environment Australia (2000) Revision of the Interim Biogeographic Regionalisation of Australia (IBRA) and the development of version 5.1. Summary report. Department of Environment and Heritage, Canberra, ACT, Australia.

Fisher A, Day M, Gill T, Roff A, Danaher T, Flood N (2016) Large-area, high-resolution tree cover mapping with multi-temporal SPOT5 imagery, New South Wales, Australia. Remote Sensing 8, 515.
| Crossref | Google Scholar |

Grierson P, Williams K, Adams M (2000) Review of unpublished Biomass-Related Information: Western Australia, South Australia, New South Wales and Queensland. National Carbon Accounting System Technical Report No. 25. Australian Greenhouse Office, Canberra, ACT, Australia.

Holm AM, Curry PJ, Wallace JF (1984) Observer differences in transect counts, cover estimates and plant size measurements on range monitoring sites in an arid shrubland. The Rangeland Journal 6, 98-102.
| Crossref | Google Scholar |

Landsberg J, Kesteven J (2002) Spatial estimation of plant productivity. In ‘Biomass estimation: approaches for assessment of stocks and stock changes’. (Ed. GP Richards) National Carbon Accounting System Technical Report No. 27. (Australian Greenhouse Office: Canberra, ACT, Australia)

McKenzie N, Ryan P, Fogarty P, Wood J (2000) Sampling, measurement and analytical protocols for carbon estimation in soil, litter and coarse woody debris. National Carbon Accounting System Technical Report No. 14. (Australian Greenhouse Office: Canberra, ACT, Australia)

Mitchell A, Wilcox D (1994) ‘Arid Shrubland Plants of Western Australia.’ 2nd edn. (UWA Press and DoA: WA, Australia)

Nguyen TT, Eslick H, Barber P, Harper R, Dell B (2022) Cooling effects of urban vegetation: the role of golf courses. Remote Sensing 14, 4351.
| Crossref | Google Scholar |

Nielsen UN, Stafford-Smith M, Metternicht GI, Ash A, Baumber A, Boer MM, Booth S, Burnside D, Churchill AC, El Hassan M, Friedel MH, Godde CM, Kelly D, Kelly M, Leys JF, McDonald SE, Maru YT, Phelps DG, Ridges M, Simpson G, Traill B, Walker B, Waters CM, Whyte AW (2020) Challenges, solutions and research priorities for sustainable rangelands. The Rangeland Journal 42, 359-373.
| Crossref | Google Scholar |

Paul K, Roxburgh S, Raison J, Lamour J, Ritson P, Brooksbank K, Carter J, England J (2011) Final Report: research on growth of environmental plantings. Prepared for Department of Climate Change and Energy Efficiency. CSIRO, Canberra, ACT, Australia.

Paul KI, Roxburgh SH, Chave J, England JR, Zerihun A, Specht A, Lewis T, Bennett LT, Baker TG, Adams MA, Huxtable D, Montagu KD, Falster DS, Feller M, Sochacki S, Ritson P, Bastin G, Bartle J, Wildy D, Hobbs T, Larmour J, Waterworth R, Stewart HTL, Jonson J, Forrester DI, Applegate G, Mendham D, Bradford M, O’Grady A, Green D, Sudmeyer R, Rance SJ, Turner J, Barton C, Wenk EH, Grove T, Attiwill PM, Pinkard E, Butler D, Brooksbank K, Spencer B, Snowdon P, O’Brien N, Battaglia M, Cameron DM, Hamilton S, McAuthur G, Sinclair J (2016) Testing the generality of above-ground biomass allometry across plant functional types at the continent scale. Global Change Biology 22, 2106-2124.
| Crossref | Google Scholar | PubMed |

Paul KI, Radtke PJ, Roxburgh SH, Larmour J, Waterworth R, Butler D, Brooksbank K, Ximenes F (2018) Validation of allometric biomass models: how to have confidence in the application of existing models. Forest Ecology and Management 412, 70-79.
| Crossref | Google Scholar |

Payne AL, Curry PJ, Spencer GF (1987) An inventory and condition survey of rangelands in the Carnarvon Basin, Western Australia. Technical Bulletin No. 73. (Western Australian Department of Agriculture: Perth, WA, Australia)

Payne AL, Van Vreeswyk AME, Pringle HJR, Leighton KA, Hennig P (1998) An inventory and condition survey of the Sandstone-Yalgoo-Paynes Find area, Western Australia. Techical Bulletin No. 90. (Agriculture Western Australia: Perth, WA, Australia)

Porfirio LL, Antille DL, Watson I, Abbott BN, Bowman DMJS, Briggs PR, Canadell JG, Churchill AC, Donohue RJ, Guerschman JP, Haverd V, Hill MJ, Knauer J, Murphy BP, Paget M, Prior LD, Roxburgh SH, Williamson GJ (2020) Productivity and biomass of Australia’s rangelands: towards a national database. The Proceedings of the Royal Society of Queensland 128, 75-98.
| Crossref | Google Scholar |

Roxburgh SH, Paul KI, Clifford D, England JR, Raison RJ (2015) Guidelines for constructing allometric models for the prediction of woody biomass: how many individuals to harvest? Ecosphere 6(3), 38.
| Crossref | Google Scholar |

Russell PJ (2007) Assessing long-term change in rangeland ecological health using the Western Australian rangeland monitoring system. PhD Thesis, Curtin University, Perth, WA, Australia. Available at https://espace.curtin.edu.au/handle/20.500.11937/1598

Russell-Smith J, Yates CP, Edwards AC, Whitehead PJ, Murphy BP, Lawes MJ (2015) Deriving multiple benefits from carbon market-based savanna fire management: an Australian example. PLoS One 10(12), e0143426.
| Crossref | Google Scholar | PubMed |

Shiono K, Suganuma H, Abe Y, Tanouchi H, Utsugi H, Saito M, Takahashi N, Kojima T, Yamada K (2006) Biomass growth estimation of an afforestation site and natural forests in an arid land of Western Australia. Journal of Arid Land Studies 15(4), 251-254.
| Google Scholar |

Sinclair R (2004) Persistence of dead trees and fallen timber in the arid zone: 76 years of data from the T.G.B. Osborn Vegetation Reserve, Koonamore, South Australia. The Rangeland Journal 26, 111-122.
| Crossref | Google Scholar |

Suganuma H, Abe Y, Utsugi H, Tanouchi H, Kojima T (2006) Shrub-land biomass estimation method for application to remote sensing. Journal of Arid Land Studies 15(4), 259-262.
| Google Scholar |

Taniguchi M, Abe Y, Yamada K, Kojima T, Williams A (1998) Possibility of large scale afforestation in arid lands as a measure against increases in CO2 concentration. Journal of Arid Land Studies 7S, 249-252.
| Google Scholar |

Tille P (2006) Soil-landscapes of Western Australia’s Rangelands and Arid Interior. Resource Management Technical Report 313. ISSN 1039-7205. Department of Agriculture and Food Western Australia, Perth, WA, Australia.

Tu Y-H, Johansen K, Phinn S, Robson A (2019) Measuring canopy structure and condition using multi-spectral UAS imagery in a horticultural environment. Remote Sensing 11, 269.
| Crossref | Google Scholar |

Turland NJ, Wiersema JH, Barrie FR, Greuter W, Hawksworth DL, Herendeen PS, Knapp S, Kusber W-H, Li D-Z, Marhold K, May TW, McNeill J, Monro AM, Prado J, Price MJ, Smith GF (Eds) (2018) ‘International Code of Nomenclature for algae, fungi, and plants (Shenzhen Code) adopted by the Nineteenth International Botanical Congress’. Shenzhen, China, July 2017. Regnum Vegetabile 159. (Koeltz Botanical Books: Glashütten, Germany) 10.12705/Code.2018

Turner B, Wells K, Bauhus J, Carey G, Brack C, Kanowski P (1999) Woody biomass methods for estimating change. National Carbon Accounting System Technical Report No. 3. Australian Greenhouse Office, Canberra, ACT, Australia.

von Unger M, Emmer I (2018) ‘Carbon Market Incentives to Conserve, Restore and Enhance Soil Carbon.’ (Silvestrum and The Nature Conservancy: Arlington, VA, USA)

Watson IW, Novelly PE, Thomas PWE (2007a) Monitoring changes in pastoral rangelands – The Western Australian Rangeland Monitoring System (WARMS). The Rangeland Journal 29(2), 191-205.
| Crossref | Google Scholar |

Watson IW, Thomas PWE, Fletcher WJ (2007b) The first assessment, using a rangeland monitoring system, of change in shrub and tree populations across the arid shrublands of Western Australia. The Rangeland Journal 29, 25-37.
| Crossref | Google Scholar |

Williams A (2000) Carbon sequestration - an alternative use for rangelands and revegetated mine dumps. In ‘Proceedings Goldfields Land Rehabilitation Group 2000 workshop on environmental management in arid and semi-arid areas’. (GLRG: Kalgoorlie, WA, Australia)

Witt GB, Noël MV, Bird MI, Beeton RJS (2009) ‘Investigating long-term grazing exclosures for the assessment of carbon sequestration and biodiversity restoration potential of the mulga lands.’ (Department of the Environment, Water, Heritage and the Arts)

Yamada K, Kojima T, Abe Y, Williams A, Law J (1999) Carbon sequestration in an arid environment near Leonora, Western Australia. Journal of Arid Land Studies 9(2), 143-151.
| Google Scholar |