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- Alternative green and cost-effective processes for ammonia production.
- Direct Electrocatalytic CO2 Reduction
- Dry (CO2) Reforming of Methane
- Energy Projects
- Highly efficient and low cost photovoltaic-electrolysis (PVE) system to generate hydrogen by harvesting the full spectrum of sunlight
- Research Poster
- Solar + Thermal CO2 Methanation
- Waste Biomass to Renewable Hydrogen
- Environmental Projects
- Photovoltaic Electrocatalysis (PVE) for production of renewable fuels
- Selective Photo-reforming of organic waste for simultaneous production of H2 and valuable organic
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- Postgraduate Research Projects
- Photoelectrochemical selective organic oxidation using composite photocatalyst with multifunctional properties
- Improving the properties of powder products for beverage applications (Industry funded PhD project)
- Techno-economic Feasibility of Power to X Pathway in Australia
- Ion kinetics in electrochemical energy conversion and storage process
- Value added chemicals produced via electrochemical CO2 reduction
- Hydrogen production with high-density single-atom catalyst (SAC)
- Carbon-based absorbent material for environmental remediation
- Novel Carbon Nanomaterials for Energy Conversion and Storage
- Combinatorial design and high-throughput screening of potential solar hydrogen photocatalysts
- Single Atom Catalysts and Nanoclusters Supported on Nanoscale Silicon Carbide/Nitrides for the Partial Oxidation of Methane using Tunable Preceramic Polymer Templates
- Next Generation Catalyst Development through Artificial Intelligence
- Photocatalytic CO2 conversion to methanol
- Next generation supercapacitors and related materials
- Seawater electrolysis for simultaneous chlorine and hydrogen production
- Single-atom catalysis on vertical graphene
- Solar energy utilisation for direct CO2 reduction to sustainable fuel
- A solar thermal-driven biomass preconditioning reactor for hydrogen generation
- Machine learning-augmented high-throughput catalyst design for NH3 synthesis
- Computational materials design of catalytic materials and water filtration membranes
- Novel nanostructured catalysts toward efficient and cost-effective fuel cell stacks
- Atomically thin two-dimensional (2D) materials for electrochemical conversion of nitrogen to ammonia
- 3D printing approaches for electrochemical conversion of nitrogen to ammonia
- Data Science for Solving the Synthesis-Structure-Function Relationships Problem for Multimetallic Nanocatalysts
- Engineering of novel ozonation activation catalysts to degrade micropollutants
- Highly Reactive Metal Oxides through Biomineralization-Driven Defect Formation
- Development of novel 3D hybrid catalyst materials toward efficient conversion of energy
- Functionalized carbon based materials for electrochemical energy applications
- Surface-plasmon enhanced catalytic CO2 conversion
- Advanced battery nanotechnologies
- Single-cluster electrocatalysis for electrical energy storage
- Two-dimensional organic-inorganic materials
- Honours Projects
- Catalysis for CO2 conversion
- Photoelectrochemical CO2 reduction using rationally designed photocathode
- Plasma Driven CO2 Methanation
- Process characterisation to assess industrial scale-up feasibility: Antimicrobial Surface Development
- Electrochemical manufacturing of renewable hydrogen peroxide
- Observing the catalysts at real-time: the dynamics of ion and mass transfer in the electrocatalytic processes
- Controlled synthesis of hierarchical vertical graphene structures
- Copper nanofibers for electrochemical conversion of nitrogen to ammonia
- Functionalised graphene for electrochemical conversion of nitrogen to ammonia
- Novel bifunctional catalysts for rechargeable zinc air batteries
- 3D printing approaches for electrocatalysis
- 2D copper-based nanomaterials for electrochemical reduction of nitrogen to ammonia
- Multi-scale 3D printing of nanomaterials using liquid crystals
- Probing photocatalysis via artificial intelligence
- Atomic-Scale Structural Modelling of Functional Nanomaterials using Hybrid Experimental/Machine Learning Techniques
- Bio-Inspired Development of Nanocatalysts
- Electrochemical Processing of Biomass for Commodity Chemical Compounds and H2 gas
- Synthesis of Functional Layered Double Hydroxide Nanoplates with Tuneable Properties
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Particles and Catalysis Research Laboratory
The School of Chemical Engineering
Tyree Energy Building
UNSW Australia NSW 2052 Australia
Telephone +61 2 9385 4361
Authorised by Director, Particles and Catalysis Research Laboratory
Provider Code: 00098G ABN: 57 195 873 179
