A natural capital accounting framework to communicate the environmental credentials of individual wool-producing businesses

2.1 Demonstration farm selection

Two comparable farms were selected for this study to demonstrate the preparation of farm-level information for use in EP&L and SEEA EA accounts. The farms are situated close to each other in the agriculturally important sheep-wheat zone of Australia; this region is also home to a recognised endangered ecological community referred to as box-gum woodland. This community occurs on moderate to highly fertile soils with rainfall ranging between 400 and 1200 mm (TSSC, 2010); it extends on a sub-coastal band to the west of the Great Dividing Range from Southern Queensland, through New South Wales (NSW) to Southern Victoria, with separated representation in regions of Tasmania. Some agricultural practices such as clearing, fertiliser use and inappropriate grazing regimes are negatively associated with the health of the box-gum woodland and its capacity to persist and deliver ES such as carbon sequestration and storage, forage production and protection of soil and water quality (Dorrough et al., 2011; McIntyre, 2008; McIntyre and Lavorel, 2007; McIntyre et al., 2002; Prober et al., 2002; TSSC, 2010). The farms were selected based on their close location, and thus, shared climate and geographical characteristics, meaning that differences in NC and environmental performance are likely to reflect differences in historical and present management.

Farm 1 is a wool and beef-producing property that, following historical clearing, fertiliser application and over-sowing with leguminous species has, since the mid-1980's, been managed in ways that minimise threats to the grassy woodland vegetation. This includes the discontinuation of cultivation and fertiliser application, implementation of intensive fencing infrastructure and planned grazing practices (short graze periods, long and planned rests for pasture recovery). Pastures are monitored regularly with stock not returned until key perennial pasture species are considered (according to the farmer’s judgement) to have recovered sufficiently such that the pasture can be re-grazed without compromising future plant vitality and survival. The cessation of fertiliser use and altered grazing strategy have resulted in natural regeneration of trees indigenous to the area and recovery of the diversity of the ground layer. This is consistent with published mechanisms (Curtis and Wright, 1993; Fischer et al., 2009; McIntyre et al., 2002; Vesk and Dorrough, 2006).

Farm 2 is a wool and timber-producing property that has been historically cleared, with grasslands either fertilised and/or replaced consistent with conventional practices for the region. In recent decades, the landholders have invested substantially in managed forestry and environmental plantings to build biodiversity and NC to support the production of wool and timber. The landholder aims to increase tree cover to 35% of the farm in the form of managed forests and habitat or shelter.

2.2 Physical estimates for EP&L input

Methods for estimating the annual contributions of primary producers to EP&L (in physical terms) are described in the following order:

• GHG emissions;

• water use (consumption);

• water pollution;

• air pollution;

• waste; and

• land use.

This is followed by descriptions of methods, coherent with the UN SEEA EA, to characterise selected aspects of the NC of each farm and to present these in NC accounts. Characterisation of NC enables estimation of ecological health and biodiversity, and ES such as carbon sequestration, and soil and waterways protection. This, in turn, can be used to faithfully represent (IFRS, 2018) a farm’s environmental performance, estimate (or explain) changes to ES production that might occur over time, and determine the environmental profit or loss (Brooke et al., 2016).

To reflect interannual variation in seasonal and market conditions, and represent the characteristic performance of the operation, this study used a multi-year average of annual data collected from each farm’s financial and operational records.

Both farms in this study carried cattle (Bos taurus) and sheep (Ovis aries). To generate EP&L metrics per unit of production of wool (Kering, 2013) (consistent with the per net value-added concepts proposed by the United Nations Environment Programme; UNCTAD, 2016), resource use was allocated to the sheep and cattle enterprises on a dry sheep equivalent (DSE) basis [1], and the ratio of sheep DSE to cattle DSE was used in the initial apportionment. Sheep enterprise resource use was apportioned between wool and meat production using the biophysical allocation factor of 41.7% for wool products (Wiedemann et al., 2016).

2.3 Spatial data and accounting for NC (EA) extent

The NCA proposed in this study follows the SEEA EA in describing NC owned and controlled by an individual entity (i.e. business, family, government) as ecological assets described in physical terms based on the type, extent and condition of the ecosystem (Ogilvy, 2015, 2020; UNSD, 2017, 2020c). Following the principles of the SEEA EA, and as NCA is applied to individual entities, the ecosystem accounting area (EAA) is the land area owned/and controlled by the entity, including property ownership and property lease for business use (Ogilvy, 2020).

EAs are contiguous spaces of a specific type of ecosystem (ecosystem type; ET) in a similar condition. Additionally, in this study, the EAA was further divided into unique management areas, such as paddocks, yards, sheds, domestic and riparian areas, to reflect that management is usually conducted at this scale. The union between these management areas and the EA creates unique ecosystem units (EUs). The basic spatial unit (BSU) for NCA is metres (m), with accounting summaries presented in hectares (ha). This approach enables individual farm accounts to be aggregated to provide information about a region or catchment.

EAAs were defined using property details sourced from local government records to create farm boundary polygons using a commercial GIS tool, FarmMap4D (FarmMap4D, 2017). Paddocks, roads and infrastructure within the property were mapped using FarmMap4D. ETs were identified using state vegetation maps for NSW (Keith and Simpson, 2017) and satellite imagery to create a polygon-based ET layer using Google Earth^TM. The resulting two layers were combined (union) using EnSym (DELWP, 2018) to generate a detailed ecological asset register (EAR) containing a list of each unique EU.

2.4 Accounting for ecosystem type and condition

Following the SEEA EA, the NC accounts were compiled using ETs drawn from the IUCN Global Ecosystem Typology v1.01 (Keith et al., 2020) with the biome of demonstration farms being T4 Temperate Woodlands. To accommodate agroforestry and silvopastoral systems sometimes used in Australia, this study developed a typology to describe the types of agroforestry observed on Farm 2 (Table 2).

Ecosystem condition is defined in the SEEA EA as the quality of an ecosystem in terms of its abiotic and biotic characteristics (UNSD, 2020a). Ecosystems with different attributes generate different ES and exhibit differences in biodiversity. To indicate the potential for a grassy woodland EU to provide a range of ecosystem goods and services, state and transition models (STM) established by ecological research relevant to the grassy woodland biome (Lavorel et al., 2015; Spooner and Allcock, 2006; Whitten et al., 2010) were applied to EUs in relatively natural condition, for both demonstration farms. The simplified STM for box gum grassy woodland (Whitten et al., 2010) was used, which provides a scientifically coherent and holistic measure of the condition of this type of ecosystem. This model was further extended to include densely forested areas in a single STM. The application of a particular state (or transition) enabled an identity to be applied to each EU, providing quantitative metrics relating to the characteristics of the ecosystems and their use as suggested by the SEEA EA (UNSD, 2020a; Table 5.2).

For more natural systems (less modified systems), estimates of the overall extent (spatial coverage) of each state (or transition) were compiled for the demonstration farm, according to the STM. Individual states have particular characteristics, such as an approximate number of native species, quantity of standing and fallen dead timber, tree canopy cover, age distribution of live trees, and approximate levels of phosphorous (P) and nitrogen (N) (Whitten et al., 2010). These characteristics give an indication of ES that are likely within a particular state. The different vegetation attributes for each state of a grassy woodland (the biome where this study was situated) are summarised in Table 1. Further details, including the fertiliser application for each state, are provided in the Supplementary Material (Table A1).

To describe the EUs of more modified, less-natural systems created by planting native and exotic trees and shrubs for agroforestry and environmental purposes, the grassy woodland STM model was extended with categories reflecting anthropogenic ES observed on the second farm. These additional states are shown in Table 2. This approach follows the IUCN approach to describing intensive anthropogenic terrestrial ES (Keith et al., 2020). See Table A1 for further details of the STM used for these modified ETs.

To reflect the use of NC for livestock production, EAs were also classified with respect to their capacity to produce good-quality forage for livestock. A land condition classification system for grazing (Very Good, Good, Fair, Poor, Very Poor; Table 3) was drawn from industry good-practice for grazing management on naturalised pastures (MLA, 2016; Queensland Government, 2017; Ryan et al., 2013; Walsh and Cowley, 2014). Principles from these were adapted to naturalised grasslands in temperate regions for this study. This approach incorporated measures used in the Ecological Outcomes Verification (EOV; Savory Institute, 2019) to verify that farms are regenerating NC associated with agricultural production (Kering and Savory Institute, 2018). The NC accounts proposed complement EOV by providing a way to organise detailed grazing condition data under the normative scale recommended by the SEEA EA (Keith et al., 2019; UNSD, 2020a).

Important aspects of NC stewardship in agriculture include the protection of waterways from agricultural impact and the encouragement of biodiversity (Bennett et al., 2014; Cole et al., 2020). The NCA in this study used the functional characteristics described in the grassy woodlands STM to characterise whether riparian zone EUs were of a type and condition to provide ES that both improved water quality and protected biodiversity associated with riparian areas.

The provisional ETs and extents established using remotely-sensed data were validated through field observations at pre-selected representative locations on the property and through interviews with the farmer regarding management history, including prior application of fertiliser, cultivation and clearing history (Ogilvy et al., 2018). Due to their expense, field observations were necessarily limited to a few representative points, with these points selected using indicators of disturbance patterns derived from the seasonal ground cover statistics generated by FarmMap4D [2] and Google Earth^TM imagery. A site was considered representative of an ET if it demonstrated a similar disturbance pattern to other areas of the same ET. The STM, and grazing land condition for areas not directly observed by the ecologist were imputed based on seasonal ground cover statistics from FarmMap4D, professional judgement and information from interviews with the producers. The EAR denotes which EUs were assessed by observation and which were imputed.

2.5 Estimating carbon storage and sequestration

Carbon stock accounts are a desirable component of SEEA EA (Ajani et al., 2013; Keith et al., 2021; Lof et al., 2017; UNSD, 2017), and carbon sequestration is a valuable ES that can be provided by agriculture. Accordingly, ex-post [3] estimates of carbon sequestration and carbon stocks should be included in NCA. Bio-carbon and soil carbon stocks in the NC of a farm enterprise can be estimated using:

• Direct measurements of biomass to provide accurate estimates of bio-carbon and soil carbon stocks, and of changes to stocks resulting in changes to EA condition, including from transitions between states (Berry et al.., 2010; Jonson and Freudenberger, 2011; Keith et al., 2000).

• Published estimates of bio-carbon and soil carbon stocks associated with different ecological communities (Cardinael et al., 2018).

• Estimates of carbon stocks and sequestration rates based on models such as the Full Carbon Accounting Model (FullCAM) tool [4] used in Australia for each of the major ETs of the farm.

Due to the reliance on empirical inputs for biomass, management and disturbance regimes, the cost and technical complexity of Approach 1 was beyond the scope of this study. It would also likely be regarded as cost-prohibitive unless the farm business was participating in research on model calibration or remote sensing technology, or could offset the costs with revenue from participation in a formal carbon offset project.

In contrast, whilst Approach 2 is a cost-effective approach to estimating carbon stocks and sequestration rates, it has limited accuracy due to the present paucity of published location-specific estimates of bio-carbon stocks and sequestration rates. Using a single lookup table for a range of locales does not allow for variation across soil types and climatic zones.

For the experimental NCA approach in this study, Approach 3 using FullCAM was used to develop a site-specific set of carbon sequestration models for each type of ES on each farm. The resulting model was then used to determine carbon stocks and sequestration rates for each state or transition relevant to that ET. Existing Emissions Reduction Fund (ERF) (CER, 2020) methodologies and parameters for FullCAM were not used because they do not allow for mixed forest-agricultural systems, do not accommodate natural grassy woodlands, sparse plantings or regeneration of trees in grazed landscapes, and do not allow for the ongoing sequestration of existing trees in addition to modelling sequestration related to regrowth (CER, 2020). Furthermore, the existing ERF methodologies require each EU to be modelled separately, which is onerous when the objective is to estimate sequestration for a whole farm.

To overcome this, models were created for each of the following scenarios to represent the EAs of the demonstration farms:

• Grassy woodlands and forests – FullCAM parameters were configured to reflect the clearing history (determined in farm interviews), present condition (position in the STM) and any expected regeneration or degradation of grassy woodland ecosystems as recorded in the ecosystem accounts. These were then assigned a carbon stock and annual sequestration rate for each of the states and transitions from the STM.

• Fully-replaced exotic plantations – to reflect these types of agroforestry assets, FullCAM parameters incorporated the species composition observed in the ecosystem accounts and their management (determined from farmer interviews), including thinning and harvest regimes.

• Fully-replaced native plantations – to reflect dense block native environmental plantings, FullCAM parameters incorporated the species composition observed in the ecosystem accounts and their management (determined from farmer interviews).

• Fully-replaced native shelterbelts – FullCAM parameters modelled the native environmental plantings in shelterbelt configuration.

To reflect the differences in the annual sequestration rates of different states in the STM, rates for the grassy woodlands model were calculated as a 20-year average (±10 years from the mid-point of the state or transition) based on the placement of the state or transition on the modelled growth curves. For replaced plantations and shelterbelts, the carbon stock levels and sequestration rates were calculated as the average of three age bands: young (0–20 years), intermediate (20–40 years) and mature (40–60 years). See Supplementary Materials (Table C1 and C2) for details of the settings used for the FullCAM models.

The resulting sequestration rates were used as look-up tables and applied to each EU in the EAR based on the ecosystem type and state, with additional controls to allow for the density of partially-replaced states (the percentage of cover of the plantations calculated using the iTree canopy tool (https://canopy.itreetools.org/) based on 100 samples) and the determination of whether an individual EU was regenerating (assigned the sequestration rate of that state or transition), static (sequestration rate of zero) or declining (assigned a negative sequestration rate based on the state or transition category of the EU).

2.6 Timeframes and reporting periods

ES such as carbon sequestration and environmental impacts such as GHG emissions and flows of pollution reported in the EP&L are measured as amounts generated between time periods (Brooke et al., 2016). By convention, under International Accounting Standards (IAS) and SEEA EA, accounting is ex-post, and the reporting period for changes to NC (EAs) and flows of ES is usually a calendar or financial year. This is also the timeframe for reporting flows of environmental impacts in EP&L (Brooke et al., 2016). Under IAS and SEEA EA, stocks of assets are measured at a point in time and the date of valuation is disclosed. While this study only measured NC stocks at one point in time, comparisons could be made with assessments at other dates to determine whether changes to NC have occurred.

3.1 Farm 1 – ecosystem accounts

The condition of the land for grazing on Farm 1 was Very Good or Good (Table 4), indicating that the use of the NC resource base for livestock production is optimised for the corresponding landscape; the land used for grazing is both productive and sustainable.

The ET extent accounts (Table 5) suggest that healthy grassy woodlands that are EAs of Farm 1 are persisting and regenerating on a property-wide basis – they are either maintaining or improving in condition. A significant proportion of the property is judged to be transitioning towards states that are closer to the reference condition, rather than remaining static or degrading. While some areas of the property are presently missing some grassy woodland species, there is no evidence in any part of the property, other than areas of domestic use and infrastructure, of complete or permanent replacement of the grassy woodland ecosystem by a different type of ecosystem. This suggests that Farm 1 is not contributing to the extinction of grassy woodland species.

As a result of the significant presence of ecological functions and processes associated with grassy woodlands, Farm 1 stores a large amount of carbon (more than 220,200 tonnes) above and below ground (Table 6). A significant proportion (almost all) of the property is transitioning to a state closer to the reference condition described in the grassy woodlands STM – it is improving in condition. As described in the methods, natural tree regeneration and maturation and stocks of coarse woody debris (CWD), are associated with these transitions and, therefore, the areas that are transitioning to higher condition states are also adding to carbon stocks on the property.

3.2 Farm 2 – ecosystem accounts

The condition of the land for grazing on Farm 2 was Very Good or Good (Table 7). This indicates that the NC resource base for livestock production is optimised for the corresponding landscape; the land used for grazing is both productive and sustainable.

As expected, given the history of clearing, grazing management and nutrient enrichment, the NCA of Farm 2 reflects the removal and replacement of some of the natural grassy woodlands with pastures and agroforestry, and the relatively (to Farm 1) degraded state of the remaining woodland areas. Table 8 illustrates this by quantifying the substantial presence of grassy woodlands in State 3 A or 3B and the extensive investment in forestry on this property. Forestry and environmental plantings include assets that have fully replaced (FR) and partly replaced (PR) the grassy woodland ET. As a result of this investment, Farm 2 still exhibits ecological diversity and a significant range of EAs associated with the production of ES common to grassy woodlands, but does this via different types of EAs. The ES generated by the replacement assets include shade and shelter for livestock (Baker et al., 2018) and habitat for a range of species, including birds and insects that are likely to provide pollination and pest predation services (Landis et al., 2000; Lavorel et al., 2015; Makim, 2017). The active growth of forestry assets also provides carbon sequestration services.

As a result of the significant investment in agroforestry, Farm 2 has a considerable amount of carbon (over 42,000 tonnes) stored in the above and below-ground biomass (Table 9).

3.3 Carbon sequestration services

The two demonstration properties are generating carbon sequestration services (Table 10). Note, this is due to normal management operations by the landholders and is not an additional activity that would enable participation in carbon markets as presently structured.

The magnitude of the estimate of sequestration for Farm 1 reflects the large extent of grassy woodland that has been, and continues to be, managed to allow for significant natural tree regeneration on this property. It is expected that the annual sequestration rate will reduce once the grassy woodland areas reach an optimal configuration that, in the property owner’s view balances the native biodiversity of the ecosystem with the productive potential, and the property owner consequently changes the management of these areas to maintain them in a more static condition to achieve those dual outcomes (an identified goal).

The magnitude of the estimate of sequestration for Farm 2 reflects the extensive tree planting and, to a lesser extent (to date), facilitated regeneration of native biodiversity in pastures. The estimated sequestration rate due to planted trees is expected to continue in the short to medium term as the property owner works towards the goal of having 35% cover for managed forest and habitat. New plantings as well as the ongoing maturation of existing plantings will contribute to this.

The sequestration rates for both properties are consistent with estimates of other agricultural properties with extensive tree planting (Doran-Browne et al., 2016). This highlights the potential for different investments in tree planting and natural regeneration to be reflected in estimates of individual farm carbon sequestration services. As mentioned earlier, modelling suggests that carbon sequestration rates will decline over time and will substantially reduce as the farm managers reach their desired balance of tree cover, landscape function and livestock production. With the current configuration of woody ecosystems, this is likely to occur in the next 30–50 years.

It should be noted that the carbon being sequestered on each farm (shown in Table 10) cannot be used for trading carbon offsets under existing schemes in Australia. The estimates provided are not calculated using a current ERF-approved methodology, and the sequestration related to the regeneration of grassy woodlands and growth of agroforestry assets is unlikely to satisfy the “newness” requirement (CER, 2017) as currently applied. Furthermore, the sequestration activities of these farms as part of their enterprise operations imply no obligations for permanence, as required by the ERF.

3.4 Inputs to Environmental Profit and Loss statement

The inputs to the EP&L are summarised for both farms. Table 11 presents the detailed calculations of GHG emissions. Results for all EP&L factors including the GHG emissions estimate are presented in Table 12. EP&L factors represent negative environmental impacts – the higher the quantity, the greater the negative impact on the environment.

These results were then combined with the resource use estimates to estimate the physical inputs for the six key areas of impact in the EP&L, as shown in Table 13.

Due to the nature of the operations on each farm, fossil fuel use is limited to small farm vehicles and tractors, and tools such as chainsaws. There is minimal mechanisation in the form of cultivation and fertiliser application on either farm, with a limited amount of forestry activities on each farm. As a result, GHG emissions are at the lower end of the range reported in other studies (25.1 ± 4.8 kg CO₂e/kg greasy wool; Wiedemann et al., 2016), and air pollution from fuel particulate matter is judged to be negligible.

The seasonal ground cover imagery statistics produced for both demonstration farms using FarmMap4D are consistent with the observations of the field ecologist in the NCA, indicating that both farms maintain ground cover significantly above the threshold for vulnerability of soil to wind and water erosion and neither farm employs cultivation that would cause air pollution from dust.

Both farms use minimal chemicals in their operations and limited fodder is purchased for livestock. When used, fodder is in the form of large bales of hay and, accordingly, they were assessed as producing negligible waste. As discussed earlier in the ecosystem accounts, both farms have pastures and riparian areas in Very Good or Good condition; this protects waterways from chemical pollution and soil from water erosion. There is no irrigation for pasture production; thus, water use (normalised stress-weighted water consumption) reflects consumption by livestock and evaporation of water from dams.

The differences in estimates for land use change reflect the different configurations of the two farms. Farm 1 has a large extent of original grassy woodland biome; thus, it is estimated that 71–74% of the original ES are being delivered by the farm despite its use for wool production. In comparison, the more highly modified configuration of Farm 2 resulted in an estimation that 52–59% of the ES of the original grassy woodland biome are provided by the farm.

As described earlier, the EP&L does not include estimates of carbon storage or sequestration. To provide a more complete and fair picture of the environmental performance of the farms, Table 14 summarises the GHG emissions and sequestration for each demonstration farm to show the net GHG performance of the two enterprises.

In summary, the accounts for both farms indicate that:

1. The NC of both properties is mostly in very good condition for grazing.

2. Farm 1 is contributing significantly to the persistence of grassy woodland ecosystems.

3. As a consequence of the extensive investment in timber plantations and environmental plantings, Farm 2 is significantly contributing to the generation of many ES that would be delivered by natural grassy woodland ecosystems.

4. Both farms are presently sequestering significant amounts of carbon based on current management practices and ecosystem conditions. In CO₂e terms, the sequestration rates for both farms exceed their emissions.

4.1 How primary producers can be included in estimates of environmental performance of apparel supply chains

Our work is the first, to our knowledge, to demonstrate how individual farm businesses can compile information about their NC and environmental performance for inclusion in both EP&L estimates and national and regional accounts under the SEEA EA.

The development of an accounting framework for environmental performance and NC at the farm level is an essential first step in quantifying the comparative performance of supply chains and providing empirical evidence for evaluation of the capacity of environmental accounting and performance reporting to improve environmental performance (Deegan, 2017; Gray, 2010). While this paper focuses on wool, the methods used are also suitable for sheep meat supply chains.

In addition to providing information useful for supply chains, the fine scale of this information can inform farm management decisions. The very detailed breakdowns of GHG emissions (for example, Table 12) showing the individual sources of emissions may be used by farm managers to make operational changes to improve performance. The presentation of information on a per kilogram of product basis, as recommended by the United Nations (UNCTAD, 2016), allows comparison of the environmental performance of different products, thus providing insights about how a change to production types may influence environmental performance. However, this may incorrectly penalise luxury goods such as fine wool, and alternate measures should be considered to ameliorate this problem (Wiedemann et al., 2019).

Comparisons of the performance of different farms can also be supported by the approach described in this paper. Comparisons of the environmental performance of different farms need to control for environmental factors such as rainfall, soil type and production type. The compiled contextual information about the farm (Table 11) provides this required information.

Our use of STM to quantify NC demonstrates how methods developed for the scientific study of the health and sustainability of ecosystems can provide scientifically coherent and holistic quantification of NC on farms. This approach is not limited to wool-producing farms. STM models of a biome are coherent with the typology described in the SEEA EA which is required for compiling aggregated accounts at the catchment, region and national scales for use in economic and land use policy design and planning. Thus, the use of STM simultaneously allows for the compilation of fine-scale information to describe the farm-scale NC and aggregation to regional or national accounts. By providing empirical evidence to improve the accuracy of agricultural ES and biodiversity loss estimates we have demonstrated a way to significantly improve the faithfulness of EP&L factors for land use and biodiversity. This approach has the potential to enable empirical measurement of the contemporary management of biodiversity and ES by wool growers in different countries so as to compare performance.

The inclusion of areas transitioning between stages in the STM typology, e.g. for grassy woodlands in Farm 1 and different ages of agroforestry in Farm 2, demonstrates a way to use single point-in-time assessments to convey the likely trajectory of ecosystem change on a farm. As significant changes to some types of NC take a long time to occur, this indicator of the future condition of the NC of the farm can assist stakeholders to understand whether the NC on a farm is likely to be degrading, sustained or regenerated.

4.2 Challenges and opportunities in preparation and use of the information

Several challenges and opportunities were revealed in preparing the information.

While it was possible to compile farm-level EP&L inputs using data already collected by farmers, this was a manual process requiring detailed analysis of financial and operational records for use in calculations. If software packages already used by farm businesses for financial and management accounting could be modified to enable automated output of environmental performance information, this would reduce the cost of compilation and improve the accuracy.

Not all information required by the EP&L was able to be estimated using information available to farmers. Measurement of air pollution from fuel use requires information about fuel quality, vehicle type and age, which is not routinely published. Accordingly, accurate compilation of farm-level air pollution cannot be performed unless local fuel suppliers and vehicle manufacturers publish this information.

To estimate carbon storage and sequestration rates, we applied methods currently used for Australia’s national GHG inventory. The application of these at the farm level revealed that these need further development to present a faithful representation of farm performance. Three issues were observed. The M-value layer of FullCAM at different points within the properties and between the properties resulted in carbon stock and sequestration rate estimates that were not consistent with the on-ground assessments of the ecologist teams who assessed the NC type and condition of the farms. Thus, ecosystem accounting assessments of NC type and condition could be utilised to calibrate and continually improve models such as FullCAM.

Existing ERF methodologies require modelling of each EU or non-contiguous asset, and this is not practical when modelling carbon sequestration across a diverse farming enterprise. This could potentially be solved by developing “lookup tables” for carbon and other attributes of different types of NC to make the accounting process easier. For example, empirical assessments of ecosystem characteristics, such as those described in the STM of this study, may be linked with “coefficients” describing their carbon sequestration and storage; this would make accounting for these attributes relatively straightforward. A similar approach could be used to associate NC of different types and conditions with attributes such as biodiversity and capacity to generate ES such as pollination and pest predation.

The approach described here of using the STM to determine sequestration rates highlights the potential for future research to establish “lookup tables” to calibrate FullCAM models via direct measurement of biomass (Approach 1 in Methods).

Estimates from tools such as FullCAM are sensitive to the input parameters and the ET and condition. We observed that estimates of sequestration rates on a per kg of wool basis magnified this sensitivity, especially for cases where estimates were close to carbon neutral. To be confident that estimates of carbon sequestration for different agricultural properties are comparable, standards for setting these parameters must be developed or the detailed parameters used in estimations must be disclosed to users of the information to help them determine their confidence in the estimations.

Finally, in reflecting on the presentation of the information via the terminology and codes presented in the summary tables, the lack of familiarity with NC in biophysical terms may make it difficult to interpret the information. This could be addressed with training and practice.

4.3 Future policy needs

The following topics require further research and policy development.

The two demonstration accounts illustrate two farm businesses that are improving their NC and exhibiting good environmental performance, including net sequestration of GHG and investment in biodiversity, in the absence of formal contracts with external parties. That is, their performance on these environmental issues is not ‘additional’ to their normal management.

Recent guidance for EP&L compilers (Brooke et al., 2016) indicates that environmental “profits” can only be accounted by a company if improvement is additional and in response to a deliberative investment. It is not presently clear in the EP&L guidance whether companies that change wool suppliers to source wool from producers with superior environmental performance can account these improvements as additional and in response to deliberative investment, and thus, as an environmental “profit”. The strict interpretation of additionality and deliberative investment may mean that an environmental “profit” can only be accounted if the wool grower demonstrates a change in performance as a result of supply chain investment. It seems somewhat perverse to exclude high-performing producers from being rewarded and recognised for their performance. Future guidance for EP&L (and other standards) should consider how to account for this.

The question of accounting for carbon sequestration presents a similar problem. At present, in Australia, the only way primary producers can be recognised for carbon sequestration is to participate in formal contracts, such as the ERF (www.cleanenergyregulator.gov.au/erf). Farms that have been sequestering carbon in amounts greater than their GHG emissions should be able to be recognised for their positive contribution to mitigating climate change, even if they do not participate in formal contracts to do so. Our SEEA EA-coherent ex-post demonstration (Ajani et al., 2013; Keith et al., 2021; UNCEEA, 2021b) of NC accounts for the two farms may provide a practical way to do so.

Finally, even if future research and technology reduce the cost of compiling farm-level information to be used in estimation of the environmental performance of supply chains and regions, a cost to farmers will remain. Considerations should be given to formalising cost-sharing by members of the supply chain and governments who stand to benefit from the preparation of this information.