Abstract
The vulnerability of the urban residential sector is likely to increase without the mitigation of growing household Ecological Footprints (energy demand, CO2 emissions, and demand for land). Analysis comparing the effectiveness and robustness of policy to mitigate the size of the housing Ecological Footprint has been limited. Here, we investigate three mitigation options: (1) reducing housing floor area, (2) improving the building envelope efficiency, and (3) reducing the carbon intensity of the electricity sector. We model the urban residential Ecological Footprint for a sub-national case study in Australia but analyse the results in the global context. We find that all three mitigation options reduce the Ecological Footprint. The success of policy to reduce household energy demand and land requirements is somewhat dependent on uncertain trajectories of future global population, affluence, and technological progress (together, global uncertainty). Carbon emissions reductions, however, are robust to such global uncertainty. By reducing the Ecological Footprint of the urban residential housing sector we see a reduction in its vulnerability to future global uncertainty, global carbon price, urban sprawl, and future energy shortages. Over the long term, such policy implementation can also be highly cost effective.
Highlights
The Ecological Footprint is an indicator which can be used to track the consumption of land and/or biotic resources and the carbon based waste of human populations
We examine the effectiveness of these policy options at a sub-national scale using a case study state in Australia (Queensland); the global context is included as it is considered integral to the success of local policy development
We used scenario analysis to investigate: (1) future uncertainty related to trajectories of population, affluence, and technological progress and (2) global carbon price to understand implications for local housing sector vulnerability
Summary
The Ecological Footprint is an indicator which can be used to track the consumption of land and/or biotic resources and the carbon based waste of human populations. The global Ecological Footprint of built land continues to increase [1] as world populations become more urbanised. Operational energy (the energy that is used in a house to function day to day), by far, accounts for the majority of the energy over the lifetime of an ‘average’ residential building [3,4]. For a typical house in Scandinavia with a lifetime of 50 years, the proportion of embodied energy is about 10 ± 15% of the operational energy. The embodied energy of a low energy house accounts for as much as 60% of the total energy use [3]
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