Sustainability, Circularity and the Just Transition Researchers
ISER researchers are working to create a better future in a broad range of projects in sustainability, circularity and the just transition to net zero emissions.
| Researchers | keywords |
|---|---|
| battery recycling | |
| battery recycling | |
| battery recycling | |
| battery recycling | |
| battery recycling | |
| battery recycling | |
| battery recycling;Ìýenergy storage and catalysis | |
| battery recycling;Ìýlow carbon solutions;Ìýenergy-water-environment nexus | |
| battery storage | |
| carbon capture and storage | |
| carbon capture and storage | |
| carbon capture and storage | |
| Dr Zizhou (Steve) Xiang | carbon capture and storage |
| carbon capture, utilisation and storage | |
| carbon capture, utilisation and storage;Ìýwaste recovery | |
| carbon emissions analytics; underground carbon and hydrogen storage simulation | |
| carbon sequestration; biodiversity conservation | |
| catalysts for energy conversion;Ìýenergy efficiency;Ìýenvironmental remediation | |
| circular economy;Ìýsolid waste recycling;Ìýrenewable energy recycling | |
| circular economy;Ìýsustainable supply chain management | |
| Prof Peter Draper | circular trade;Ìývalue chains |
| climate change | |
| climate change | |
| climate change | |
| climate change | |
| climate change | |
| climate change | |
| climate change adaptation; natural hazards | |
| climate change governance;Ìýsocially just transitions | |
| Dr Tracey Dodd | climate change;Ìýsustainability and circularity;ÌýESG, renewable energy policy |
| cybersecurity theory and applications; robotic and autonomous systems; automation and control systems design; faulty detection, analysis and resilience | |
| James Hancock | economics of sustainable energy |
| Anthony Kosturjak | economics of sustainable energy |
| (eco)systemic perspectives of transition to circularity | |
| energy storage and creation | |
| energy storage and creation | |
| energy storage and creation | |
| energy storage and creation | |
| energy storage and creation | |
| energy storage and creation | |
| energy storage and creation | |
| energy storage and creation;Ìýsustainability and circularity | |
| geoethics;Ìýcarbon capture and storage;Ìýjust sustainable transition | |
| geophysics for exploration;Ìýgeothermal energy | |
| geo-zero;Ìýcarbon sequestration | |
| humanitarian technologies | |
| innovative and sustainable mining technologies | |
| material-specific sensing;Ìýoptical sensing;Ìýcritical minerals sensor technology | |
| pathway to low-cost large-scale net-zero hydrogen production | |
| pathway to low-cost large-scale net-zero hydrogen production | |
| radioactive waste | |
| renewable energy and law | |
| renewable energy systems | |
| renewable energy systems | |
| sustainability | |
| sustainability | |
| sustainability;Ìýcircularity;ÌýESG;Ìýe-waste recycling;Ìýrecovery of critical minerals from e-waste | |
| sustainable buildings | |
| sustainable buildings | |
| sustainable materials development for plant growth and metal recovery | |
| sustainable supply chain management | |
| sustainable value chains | |
| sustainable water | |
| sustainable water and energy | |
| underground waste management (e.g. paste backfill); sustainable mine design; monitoring and mitigation of geotechnical hazards; minimising ground failure resource loss | |
| A/Prof Charlie Hargroves | urban sustainability;Ìýnet-zero strategies;Ìýdecentralised energy;Ìýsustainable transport |
| urban sustainability;Ìýsustainable urban transitions | |
| urban water management | |
| using autonomous precision technology for sustainable farming and defence applications |
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