Aboveground biomass relationship with canopy cover and vegetation to improve carbon change monitoring in rangelands

Rangelands cover vast areas of the global land surface and are important to the terrestrial carbon budget. However, carbon accounting in rangeland systems is often limited by the lack of transparent and systematic methods for assessing changes in aboveground biomass (BAG). Although relationships between BAG and canopy cover, C, have been investigated at site and regional scales, there are few studies across regions where the impact of a range of vegetation types and site conditions has been assessed. Here, results were compiled from extensive field measurements across 431 Australian rangeland sites (covering an area of ~6 million km2) to develop empirical relationships to predict BAG from C and other structural variables. A boosted‐regression‐tree model was trained to identify the relative importance of predictor variables. Then, based on these results, a stepwise empirical log‐linear relationship was developed to estimate BAG. About 70% of the BAG could be described using C, the percentage of large trees (stem diameter >50 cm), and height. Because such detailed information is not yet available at sufficient spatial and temporal resolution, classifications based on existing maps of structural vegetation classes, using C as the single predictor variable, were explored as an alternative approach to estimate BAG. For most structural vegetation classes assessed, estimates of BAG from C were statistically significant, with Lin's concordance coefficients of 0.67–0.79 and proportional error of <36% relative to the BAG across all the classes. There was generally little improvement in model performance with the inclusion of additional explanatory variables. Overall, this study has improved our understanding of relationships between C and BAG across rangeland systems. Additionally, combining remotely sensed woody cover data with these relationships may offer a transparent and accurate approach to monitor changes in biomass carbon stocks in these ecosystems at a large spatial scale.

• Publication year

  2025

• Venue

  Ecosphere

• Publication date

  2025-04-01

• Fields of study

  Not labeled

• Identifiers
  DOI 10.1002/ecs2.70231
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar

• No claims are published for this paper.

• No concepts are published for this paper.

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