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Decarbonization of Australia’s Energy System: Integrated Modeling of the Transformation of Electricity, Transportation, and Industrial Sectors

Author

Listed:
  • Tino Aboumahboub

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany)

  • Robert J. Brecha

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany
    Physics Department, Renewable and Clean Energy Program, and Hanley Sustainability Institute, University of Dayton, 300 College Park, Dayton, OH 45469, USA)

  • Himalaya Bir Shrestha

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany)

  • Ursula Fuentes

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany
    School of Engineering and Energy, Murdoch University, 90 South Street, Murdoch WA 6150, Australia)

  • Andreas Geiges

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany)

  • William Hare

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany)

  • Michiel Schaeffer

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany
    The Global Center on Adaptation, Wilhelminakade 149C, 3072 AP Rotterdam, The Netherlands)

  • Lara Welder

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany)

  • Matthew J. Gidden

    (Climate Analytics gGmbH, Ritterstr. 3, 10969 Berlin, Germany
    International Institute for Applied Systems Analysis, Schlossplatz 1, A-2361 Laxenburg, Austria)

Abstract

To achieve the Paris Agreement’s long-term temperature goal, current energy systems must be transformed. Australia represents an interesting case for energy system transformation modeling: with a power system dominated by fossil fuels and, specifically, with a heavy coal component, there is at the same time a vast potential for expansion and use of renewables. We used the multi-sectoral Australian Energy Modeling System (AUSeMOSYS) to perform an integrated analysis of implications for the electricity, transport, and selected industry sectors to the mid-century. The state-level resolution allows representation of regional discrepancies in renewable supply and the quantification of inter-regional grid extensions necessary for the physical integration of variable renewables. We investigated the impacts of different CO 2 budgets and selected key factors on energy system transformation. Results indicate that coal-fired generation has to be phased out completely by 2030 and a fully renewable electricity supply achieved in the 2030s according to the cost-optimal pathway implied by the 1.5 °C Paris Agreement-compatible carbon budget. Wind and solar PV can play a dominant role in decarbonizing Australia’s energy system with continuous growth of demand due to the strong electrification of linked energy sectors.

Suggested Citation

  • Tino Aboumahboub & Robert J. Brecha & Himalaya Bir Shrestha & Ursula Fuentes & Andreas Geiges & William Hare & Michiel Schaeffer & Lara Welder & Matthew J. Gidden, 2020. "Decarbonization of Australia’s Energy System: Integrated Modeling of the Transformation of Electricity, Transportation, and Industrial Sectors," Energies, MDPI, vol. 13(15), pages 1-39, July.
    • Handle: RePEc:gam:jeners:v:13:y:2020:i:15:p:3805-:d:389453
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    References listed on IDEAS

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    5. Omoseni Oyindamola Adepoju & Love Opeyemi David & Nnamdi Ikechi Nwulu, 2022. "Analysing the Impact of Human Capital on Renewable Energy Penetration: A Bibliometric Reviews," Sustainability, MDPI, vol. 14(14), pages 1-20, July.
    6. Bogdanov, Dmitrii & Gulagi, Ashish & Fasihi, Mahdi & Breyer, Christian, 2021. "Full energy sector transition towards 100% renewable energy supply: Integrating power, heat, transport and industry sectors including desalination," Applied Energy, Elsevier, vol. 283(C).
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