Abstract
Background, aim, and scope
Under ISO 14040, normalisation is an optional step in life-cycle impact assessment designed to provide environmental context by indicating the relative contribution that the product system under investigation makes in the various impact categories, in comparison to a suitable reference scenario. The challenge for many studies, however, is to provide the appropriate context by adopting a normalisation reference scenario that is well matched to the product system’s parent environment. Australia has a highly urbanised population, mainly contained in just eight capital cities. In the context of normalising environmental impacts against the profile of an ‘average’ Australian, this poses a unique problem, compared to other industrialised regions of the world. This study aims to use publicly available data on environmentally relevant emissions and non-renewable resource consumption in 2005/2006 to develop regional normalisation data for Australia, at both inventory and characterisation levels.
Methods
The regionalised inventory of emissions and resources production is constructed using a framework of 60 regional Statistical Divisions from the Australian Standard Geographical Classification system. Data from the National Pollutant Inventory, Australian Greenhouse Emissions Information System and the Australian Bureau of Agricultural and Resource Economics (energy and mineral statistics) are used as the basis for the inventories. These data could subsequently be used by any LCA practitioner to construct characterisation or normalisation data by impact category, according to any preferred life-cycle impact assessment methodology, for any of 60 regions in the country. In this study, the regionalised inventory data were assessed using the CML 2001 baseline and IMPACT 2002+ life-cycle impact assessment methods in SimaPro v.7.1.5.
Results
Characterisation results from the two LCIA methods for Australia’s eight state and territory capital cities are presented, together with an overall national profile. These data are also shown on a per capita basis to highlight the relative environmental profiles of citizens in the different cities. Interestingly, many significant impacts occur outside of the capital cities but are linked to facilities providing the majority of their services and products to these urban centres (e.g. power stations, minerals processing). Comparison of the average Australian data with the Netherlands, Western Europe and the World shows the results to be broadly similar.
Discussion
Analysis of the CML 2001 baseline characterisation results, on a per capita basis, shows substantial differences between the major cities of the country. In each impact category, these differences can be successfully traced to specific emissions in the raw data sources, the influence of prevailing climate conditions, or factors such as the mix of non-renewable energy resources in each state. Some weaknesses are also evident in the collection and estimation techniques of the raw data sources and in the application of European-based impact assessment models. Australia is a net exporter of many products, particularly natural resources. Therefore, a significant part of the characterisation data presented here for Australia represents products that will be consumed in other parts of the world. Similarly, at a regional level, there will be many inventory items produced in one area yet consumed in another. In this way, the impacts associated with consumption (particularly in densely populated but largely industry-free cities) are dissipated into other production centres.
Conclusions
This study provides the first set of comprehensive inventory and characterisation data for Australia from a production perspective, disaggregated at a regional level. Despite Australia’s unique spatial demography, it is now possible to properly characterise the relative significance of environmental impacts occurring in any of 60 specific regions across the country.
Recommendations and perspectives
Australia’s unique concentration of urban populations demonstrates the importance of regionally specific environmental assessments. Whilst the data presented in this study will be of most use to Australian LCA practitioners, it is also demonstrative of the broader global distribution of environmental impacts between urban and non-urban areas. The disconnection of environmental impacts between the place of production and the place of consumption is highlighted by this study and should be considered in any studies using these normalisation data for environmental profiling.
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Acknowledgements
The authors thank Murray Hall of CSIRO Sustainable Ecosystems for his valuable contribution to this paper.
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Responsible editor: Martin Baitz and Jeroen Guinée
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Supporting Information 1
NPI data by substance and ASGC Statistical Division (2005/2006) (PDF 491 kb)
Supporting Information 2
AGEIS data by greenhouse gas and State (2005) (PDF 10 kb)
Supporting Information 3
ABARE energy production by fuel type and state (2005/2006) and mineral production, imports and exports by mineral type (2005/2006) (PDF 15 kb)
Supporting Information 4
Characterisation results for capital cities and Australia by CML 2001 baseline LCIA methodology (PDF 13 kb)
Supporting Information 5
Characterisation results for capital cities and Australia by IMPACT 2002+ LCIA methodology (PDF 37 kb)
Supporting Information 6
Unassessed items from inventory characterisation by CML 2001 baseline and IMPACT 2002+ LCIA methods (PDF 13 kb)
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Foley, J., Lant, P. Regional normalisation figures for Australia 2005/2006—inventory and characterisation data from a production perspective. Int J Life Cycle Assess 14, 215–224 (2009). https://doi.org/10.1007/s11367-009-0063-y
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DOI: https://doi.org/10.1007/s11367-009-0063-y