| ID | 118843 |
| Title Proper | Impacts on the biophysical economy and environment of a transition to 100% renewable electricity in Australia |
| Language | ENG |
| Author | Turner, Graham M ; Elliston, Ben ; Diesendorf, Mark |
| Publication | 2013. |
| Summary / Abstract (Note) | We investigate the impacts on the biophysical economy, employment and environment of a transition scenario to an energy-efficient, 100% renewable electricity (RE) system by 2060, based on wind, solar and biomass technologies, and an introduction of electric vehicles. We employ a CSIRO process-based model of the physical activity of Australia's economy and environmental resources, the Australian Stocks and Flows Framework. The RE systems are assumed to be manufactured in Australia to identify possible employment benefits. In comparison with the business-as-usual (BAU) scenario, on a national scale, the RE scenario has much lower economy-wide net emissions, remaining below contemporary levels and becoming zero in the electricity sector by 2060. Compared with BAU, the RE scenario also has significantly lower industrial water use, somewhat higher materials use, slightly lower unemployment, lower net foreign debt (relative to a GDP proxy) and, resulting from the growth in electric vehicles, reduced oil imports. The GDP per capita growth, based on the physical stocks of capital and labour, is virtually the same in both scenarios. Hence, from the viewpoint of the biophysical economy, there are no major barriers to implementing policies to facilitate the transition to a 100% renewable electricity system for Australia. |
| `In' analytical Note | Energy Policy vol. , No.54; Mar 2013: p.288-299 |
| Journal Source | Energy Policy vol. , No.54; Mar 2013: p.288-299 |
| Key Words | Renewable Energy ; Biophysical Economy ; Scenario Simulation |