Discovery Early Career Researcher Award - Grant ID: DE180100190
Funder
Australian Research Council
Funding Amount
$363,996.00
Summary
Auction design with behavioural bidders. This project aims to incorporate behavioural elements from psychology into the economic analysis of auctions. The project will address discrepancies between traditional economic analysis of auctions based on fully rational bidders, and evidence from psychology and behavioural economics which demonstrates systemic departures from rational decision-making. This will expand realism in economic analysis and contribute new insights for the design of relevant, ....Auction design with behavioural bidders. This project aims to incorporate behavioural elements from psychology into the economic analysis of auctions. The project will address discrepancies between traditional economic analysis of auctions based on fully rational bidders, and evidence from psychology and behavioural economics which demonstrates systemic departures from rational decision-making. This will expand realism in economic analysis and contribute new insights for the design of relevant, real-world auctions such as real-estate auctions or internet auctions. The project outcomes are expected to enhance the efficient allocation of resources, improve our understanding of how different rules affect buyers' well-being and help design fairer auctions.Read moreRead less
Information and market design: mediation and analogical argumentation. This project aims to increase knowledge of how judicious disclosure of information facilitates economic exchange and social interactions and to shed light on how mediation can be an effective mode of dispute resolution. The project seeks to uncover how analogical arguments can be persuasive and determine social outcomes as well as provide guidance for advocates and decision makers on the best way to persuade and counteract mi ....Information and market design: mediation and analogical argumentation. This project aims to increase knowledge of how judicious disclosure of information facilitates economic exchange and social interactions and to shed light on how mediation can be an effective mode of dispute resolution. The project seeks to uncover how analogical arguments can be persuasive and determine social outcomes as well as provide guidance for advocates and decision makers on the best way to persuade and counteract misleading persuasion practices. Besides producing significant new knowledge, the project promises to inform future innovative economic, social and cultural developments of benefit to the Australian and international community.Read moreRead less
Redesigning Landcare policy to better coordinate across landholders. This project aims to study how landscape-sensitive economic incentives and social norms can be leveraged to enhance the short- and long-term effectiveness of conservation programs. It will yield new knowledge for innovative designs in conservation contracting that is urgently needed to address worsening environmental threats in Australia and worldwide. In collaboration with Nobel laureate Vernon Smith’s team, new methods and pr ....Redesigning Landcare policy to better coordinate across landholders. This project aims to study how landscape-sensitive economic incentives and social norms can be leveraged to enhance the short- and long-term effectiveness of conservation programs. It will yield new knowledge for innovative designs in conservation contracting that is urgently needed to address worsening environmental threats in Australia and worldwide. In collaboration with Nobel laureate Vernon Smith’s team, new methods and protocols will improve our ability to generate better data and better understand how social and incentive mechanisms can constructively interact to facilitate collaborative environmental action. Results will help make the achievement of environmental targets and the use of public funds more cost-effective. Read moreRead less
Chlorine Evolution Catalysts for Efferent Seawater Electrolysis. Seawater is the most abundant aqueous resource on earth that is readily accessible at very low costs, but yet to be directly utilised for production of hydrogen fuel and commodity chemicals. This project aims to develop cheap and plentiful carbon-based high performance chlorine evolution electrocatalysts for seawater electrolysis powered by renewable electricity to realise the production of hydrogen, chlorine and sodium hydroxide d ....Chlorine Evolution Catalysts for Efferent Seawater Electrolysis. Seawater is the most abundant aqueous resource on earth that is readily accessible at very low costs, but yet to be directly utilised for production of hydrogen fuel and commodity chemicals. This project aims to develop cheap and plentiful carbon-based high performance chlorine evolution electrocatalysts for seawater electrolysis powered by renewable electricity to realise the production of hydrogen, chlorine and sodium hydroxide directly from seawater. The electrolyser can also be used to treat desalination brine while produce hydrogen and chemicals. The success of the project will set a firm technological foundation for seawater utilisation, which will add to Australian capability to meet future energy and environment challenges.Read moreRead less
Plasmonic nanoparticle catalysis for nitrogen-based synthesis. Light can generate an optical force to capture small objects. This requires intense light – a laser, which limits optical trapping in catalysis applications. This project aims to apply plasmonic nanoparticles with normal-intensity light to take advantage of plasmonic-generated optical forces for catalytic chemical synthesis. The optical trapping/releasing of small molecules is highly selective and responsive to molecule structure and ....Plasmonic nanoparticle catalysis for nitrogen-based synthesis. Light can generate an optical force to capture small objects. This requires intense light – a laser, which limits optical trapping in catalysis applications. This project aims to apply plasmonic nanoparticles with normal-intensity light to take advantage of plasmonic-generated optical forces for catalytic chemical synthesis. The optical trapping/releasing of small molecules is highly selective and responsive to molecule structure and so presents a great opportunity to radically alter chemical synthesis pathways, which will be illustrated with reactions on liquid-solid and gas-solid interfaces. This highly innovative strategy will be used to discover new nitrogen-based syntheses which are both fundamentally and industrially important.Read moreRead less
Nanostructured solid acid catalysts for sustainable chemical manufacturing. This project aims to develop next-generation solid acid catalysts for energy- and atom-efficient transformations of waste biomass and carbon dioxide to sustainable chemicals and fuels. Catalysis is a transformative technology, key to both life and lifestyle, contributing to 90% of chemical manufacturing processes and >20% of all industrial products, and will be a key enabler for the emerging Australian bioeconomy. The ex ....Nanostructured solid acid catalysts for sustainable chemical manufacturing. This project aims to develop next-generation solid acid catalysts for energy- and atom-efficient transformations of waste biomass and carbon dioxide to sustainable chemicals and fuels. Catalysis is a transformative technology, key to both life and lifestyle, contributing to 90% of chemical manufacturing processes and >20% of all industrial products, and will be a key enabler for the emerging Australian bioeconomy. The expected development of new high performance catalysts for the production of renewable transportation fuels and sustainable chemical feedstocks will underpin commercially viable low carbon technologies using waste resources, and should provide significant benefits to Australian science, industry, and the environment.
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Discovery Early Career Researcher Award - Grant ID: DE210101102
Funder
Australian Research Council
Funding Amount
$404,748.00
Summary
Single-Atom Catalysts on Atomically Thin Nanomaterials for H2O2 Production. Single-atomic sites supported on graphene analogs is an ideal structural mode for the design of electrocatalysts due to its ultimate small size limit, atomic thickness, and easily tuned electronic properties. This project aims to use a theory-guided approach to develop efficient electrocatalysts for the production of value-added hydrogen peroxide. The structural advantages of graphene analogs will be fully utilised to un ....Single-Atom Catalysts on Atomically Thin Nanomaterials for H2O2 Production. Single-atomic sites supported on graphene analogs is an ideal structural mode for the design of electrocatalysts due to its ultimate small size limit, atomic thickness, and easily tuned electronic properties. This project aims to use a theory-guided approach to develop efficient electrocatalysts for the production of value-added hydrogen peroxide. The structural advantages of graphene analogs will be fully utilised to unlock the catalytic power of single-atomic sites, and consequently achieve high catalytic activity and selectivity. The outcome will set a solid scientific foundation to enable economically viable technologies for eco-friendly hydrogen peroxide production and bring significant socioeconomic benefits to Australia.Read moreRead less
Promoting transition metal complex catalysis with plasmonic antennae. This project aims to apply visible light photocatalysis to a wide range of chemical reactions by utilizing the intriguing effects of intense light absorption by plasmonic metal nanoparticles, such as generating energetic electrons, changing reactant adsorption and the chemical binding of reactant with the catalyst. These effects will promote catalysis at surface-bound metal complex reaction sites under mild reaction conditions ....Promoting transition metal complex catalysis with plasmonic antennae. This project aims to apply visible light photocatalysis to a wide range of chemical reactions by utilizing the intriguing effects of intense light absorption by plasmonic metal nanoparticles, such as generating energetic electrons, changing reactant adsorption and the chemical binding of reactant with the catalyst. These effects will promote catalysis at surface-bound metal complex reaction sites under mild reaction conditions. This is a part of our long-term effort to transform chemical production by heating into green photocatalytic process. This project expects to generate knowledge crucial for developing theories for catalysis, the design of efficient catalysts, green chemical synthesis methods, and enhance international collaboration.Read moreRead less
Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliv ....Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliver a high performance coating for the production of drag reduction surfaces, but allow these surfaces to be tailored to specific application profiles including UV resistance and anti-fouling properties. The project will place an Australian company at the forefront of drag reduction technologyRead moreRead less
Precision-built dynamic and functional polymer vesicles. The project aims to create new precision-built polymer vesicles with controlled size, stability, functionality and environmental responsiveness to mimic some of the key dynamic functions of the cell. The project expects to generate new knowledge on the dynamic interplay between the polymer and its bilayer including on-demand activated polymerisations and reactions, logic gates and in situ sensors. Expected outcomes of this project include ....Precision-built dynamic and functional polymer vesicles. The project aims to create new precision-built polymer vesicles with controlled size, stability, functionality and environmental responsiveness to mimic some of the key dynamic functions of the cell. The project expects to generate new knowledge on the dynamic interplay between the polymer and its bilayer including on-demand activated polymerisations and reactions, logic gates and in situ sensors. Expected outcomes of this project include new synthetic polymer techniques and new quantitative insights into the role of compartmentalisation on chemical reactions and polymerisations. This project will provide fundamental knowledge on bio/polymer vesicles with great potential to advance the polymer industry in Australia.Read moreRead less