Open lab week
Week 6 (15 and 16 October 2024)
Join us in Week 6 of T3 (15 and 16 October 2024) for two days of great opportunities to learn about the exciting research in the School of Chemical Engineering. You will have the chance to visit our research labs informally and chat with our academics about their latest research findings and future projects. You will see our state-of-the-art research facilities during lab tours, and you will have the chance to get first-hand info from some of our PhD and postdoctoral researchers.
It doesn’t matter if you are a first-year, final-year, or a postgraduate student - everyone is invited! Learn more about possibilities for your future research/honours thesis or what a PhD/MPhil project could look like. Did you know that there are many exciting scholarship opportunities in our School?
More info about the different research areas in the School can be found here:
Below the blue signup button, you can find an overview of this term’s offerings (please expand the sections of each academic to learn more about available time slots, meeting locations and research areas)
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Meeting location:
Science and Engineering Building, E8, Room 309, Lv3
Timeslot(s):
Tuesday 11:00, Tuesday 13:00
Research Area(s):
Food and Health: Understanding the role of micro and macronutrients and their impact on health and nutrition in humans
Research Overview:
Arcot’s group focuses on food-based approaches to understanding biochemical and physiological effects of nutrients and bioactives in humans aiming to provide a better understanding of their functions, interactions in food matrices, and absorption in humans using stable isotope techniques, and in vitro 2D and 3D (organoid) cell culture models to mimic the human physiological system. They also involve development of these protocols by collaborating with cancer cell biologists as a cross-disciplinary approach to understanding nutrient absorption. Her projects lead to developing sustainable foods with better nutritional quality by industry. Her work has identified ways to combat malnutrition through fortification of foods in Asia, Africa and the Pacific. She has worked with industry on several projects to address the need to improve protein availability from plant-based foods including from extracting protein from waste (agricultural and manufacturing stream wastes), from edible leaves. In addition, her projects focus on enhancement of Vitamin B12 and iron in plant foods through fermentation; bioactives in foods and their health properties. Her team of researchers currently focus on the bioavailability of Vitamin B12 and iron interactions with plant proteins to have a more wholistic approach to the development of plant-based protein foods; bioactives (carotenoids) in foods and their impact on eye health. Her work on the quantification and bioavailability of folate from foods were taken on board for development of the folate fortification policy in Australia and as an invited member of the Folate Technical Advisory Group of FSANZ. All research done within the group lead to real-world health impacts on populations. Her involvement as a member of the International Humanitarian Network has also lead to collaborations in Africa and Asia to focus on protein malnourishment. The collaborations with the food industry and other international organisations reinforce the link between academic expertise and population health.
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Meeting location:
Science and Engineering Building, E8, Room 331, Lv3
Timeslot(s):
Tuesday 15:00, Wednesday 13:00
Research Area(s):
Polymer chemistry, nanomedicine, energy, 3D printing
Research Overview:
The Boyer research group is focused on the development of new polymer synthesis strategies using visible light, for the fabrication of nanostructured materials, which can find applications as advanced smart materials in the fields of energy and nanomedicine. We combine modern polymer synthesis with emerging chemical engineering processes such as 3D printing, flow chemistry, and high throughput methods to prepare nanostructured materials featuring advanced properties and functions. Our research is highly interdisciplinary and collaborative with numerous groups in chemistry, engineering, materials science, and medicine. By combining polymerisation techniques, we have developed nanostructured 3D printed materials with enhanced mechanical properties that find applications in the energy and the biomedical fields. We also aim to design synthetic polymers capable of fulfilling specific biological functions. Such as the design of synthetic polymers capable to be used as next generation of antiviral, anticancer, and antimicrobial agents. By turning the structure of the polymers, we design new delivery systems for the treatment of hard-to-treat diseases in collaboration with clinicians.
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Meeting location:
Science and Engineering Building, SEB E8, Level 4, Room 423
Timeslot(s):
Tuesday 14:00, Wednesday 16:00
Research Area(s):
3D printing and nanostructured materials
Research Overview
Corrigan’s group focusses on the development of advanced polymer and hybrid materials using highly accessible and inexpensive visible light 3D printing techniques. Using 3D printing, we can create nanostructured materials in a matter of minutes, which significantly simplifies the production process. These materials have complex 3D structures at the nanoscale, and can also be 3D printed into different shapes depending on the required application. Due to their unique properties, the nanostructured materials that we 3D print can be used in fields as diverse as energy storage, healthcare, and environmental science. By using affordable and widely available processes, we can reduce the costs of 3D printing, making high-value materials more accessible to a broader audience.
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Meeting location:
Hilmer Building, Room 521, Lv5, entry through Science and Engineering Building, E8
Timeslot(s):
Tuesday 13:00, Wednesday 10:00
Research Area(s):
Water and wastewater treatment and recycling, desalination, membrane processes, algae treatment
Research Overview:
In our research, we use fundamental Chemical Engineering principles to understand complex environmental systems and their interactions with our modern life to enable the development of sustainable engineering solutions. Our current research activities aim to improve water and wastewater treatment and reuse, including sea and brackish water desalination, enable technology for resource recovery and the circular economy, and develop new environmental monitoring techniques. This has included optimising treatment of harmful algae blooms, characterisation of natural organic matter in water catchments, and the use of conventional membrane technologies (from microfiltration to reverse osmosis) and investigating emerging membrane systems like forward osmosis. In particular, further implementation of membranes in low SES (socio-economic status) regions could have a great impact on the local communities, and humanitarian projects are also conducted. Our research is often developed in in close partnership with technology designers, operators, and other stakeholders (like health regulators) and result in better asset and knowledge management of the treatment processes. For example, a long-term project in collaboration with the water utility in Western Australia aims to assess and manage the risk of contamination of pathogens like Legionella.
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Meeting location:
SEB 334
Timeslot(s):
Wednesday 14:00
Research Area(s):
Theory, computation, machine learning, energy
Research Overview:
My research group is interested in understanding and designing nanomaterials using theory, computation and data-driven methods. We do so by collaborating with experimentalists in relevant areas. Currently, we focus on applications including catalytic systems, batteries, functional polymers and water/gas separation membranes.
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Meeting Location:
Kens Hilmer, E10, Room 222, Lv2
Timeslot(s):
Tuesday 14:00; Wednesday: 15:00
Research Area(s):
Understanding and Development of Advanced Rechargeable Batteries for EV and Renewable Storage Applications
Research Overview
Storage and release (charge/discharge) of energy in/from batteries rely on a few fundamental transport mechanisms: electronic/ionic transport in the solid electrodes and ionic transport in the liquid and across solid/liquid interfaces. Facilitating and controlling these transport pathways hold the key to developing higher-performance batteries with greater reliability and safety than those available in today’s market, which is the key focus of our research team. Our current goal is the development of high-energy and safe lithium solid-state batteries for portable (e.g., electric transport) applications, and aqueous zinc batteries for stationary – renewable, grid, residential, and industrial – storage. We are doing so through understanding and improving the performance of materials and electrochemical systems, unveiling and validating performance under scaled-up conditions, and engineering tools and methods to probe operation in real-time. As we have demonstrated already, translation of innovation through commercialisation lies at the heart of our research and development endeavours.
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Meeting location:
Science and Engineering Building, E8, Room 3, Lv3, meet in front of the lift at level 3
Timeslot(s):
Tuesday 16:00; Wednesday 10:00
Research Area(s):
Food and Allergy Research: Molecular Allergology, Molecular Design of Food, Biomarker Discovery and Diagnostics Technology
Research Overview
Of food-related health conditions, food allergy is no longer a rare condition and is recently recognised as a chronic disease of our time by the federal government. My “Food and Allergy research” program integrates food science and molecular allergology to study food immunology and allergy. My team aim to alleviate food allergies through dietary intervention and immunotherapy and better diagnostics. Our team focuses on molecular characteristics of allergens, and their relationship with food processing and allergic sensitisation, in view to develop food-based therapeutics or nutraceuticals with immunomodulating properties. We also focus on engineering nanoallergen delivery systems functionalised with novel dietary adjuvants from food sources. Immuno-based diagnostic tests are an important component integrated into the program. We design immunogens and generate bioaffinity molecules for wide-ranging targets from toxins to allergens, and develop immunoassays and immunosensors. We collaborate with to identify epitope-markers for developing non-invasive allergy diagnostic tools in future.
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Meeting location:
Science and Engineering Building, E8, Room 320, Lv3
Timeslot(s):
Wednesday 11:00
Research Area(s):
Nanotechnology, bionics, nano-biohybrids, biocatalysis, disease diagnosis
Research Overview
My research group is interested in developing smart biohybrid nanosystems by interfacing bioactive compounds with functional nanomaterials, making it possible to perform desired tasks rapidly and efficiently when needed. These systems will have great potential for advanced energy and biotechnological applications. Some interesting research we have been developed so far include bionic plants for environmental sensing, nano-submarines for drug delivery and cancer diagnosis, and artificial cells for smart insulin delivery.
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Meeting location:
Tyree Energy Technologies Building, Rm 366-368, Lv3
Timeslot(s):
Tuesday 12:00, Wednesday 12:00
Research Area(s):
nanoparticles, catalysis, energy, hydrogen, carbon dioxide
Research Overview:
The Particles and Catalysis Research Group (PartCat) is a leading (photo(electro)) catalysis research group within the School of Chemical Engineering at the University of New South Wales. Lead by Scientia Professor Rose Amal, PartCat focuses on understanding catalysis (photo/electro/thermal) and designing new catalytic system. Our experimental research focuses on design, synthesis, catalytic activity testing, and materials characterisation of the catalysts with the aim to gain theoretical insight into reaction mechanism. Our lab is equipped with material characterisation instrument and catalytic rig/reactor set up for activity testing capable of operating at high temperature and pressure. With operando and in-situ characterisation techniques and strong theoretical support from our collaborators, we strive to develop fundamental understanding on how catalyst work and of processes importance for sustainable energy conversion and production of fuels and chemical. Our projects cover a range of applications in catalysis such as carbon dioxide conversion, hydrogen production and ammonia synthesis.
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Meeting location:
Science and Engineering Building, E8, Room Hilmer 316A, Lv3
Timeslot(s):
Tuesday 16:00; Wednesday 16:00
Research Area(s):
polymers, surfactants, nanoparticles, consumer products
Research Overview:
The interactions between polymers, surfactants, nanoparticles and oil droplets are the building blocks by which complex fluids products are designed. The composition and manufacturing steps for pharmaceuticals, cosmetics, shampoos, cleaners, and paints need to be carefully engineered to deliver an effective product. However, the details of how product function is derived from composition are largely missing for many complex fluids products. As we look to decarbonise the chemical industry, to reformulate products to remove unsustainable or environmentally problematic chemicals, our lack of basic knowledge about polymer and surfactant systems becomes limiting. Working with industry partners, we are investigating the fundamental behaviour of molecules at interfaces, new experimental approaches to measuring interfacial properties relevant to formulation problems, and the application of these developments to real product formulation projects.
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Meeting location:
Science and Engineering Building, E8, Room 409, meet in front of the lift at level 4
Timeslot(s):
Tuesday 12:00; Wednesday 14:30
Research Area(s):
microencapsulation, spray drying, functional particles, food engineering
Research Overview:
My team is doing research related to particle and drying technologies, particularly for functional food applications. A unique capability is in functional particles assembly via microfluidic spray drying. The microfluidic spray dryer can be used to produce different types of particles, including thermal sensitive and bioactive particles, microparticles for controlled release and microencapsulation, magnetic and fluorescent composites, and mesoporous microspheres with hierarchal structures and properties superior to those observed on nanomaterials. The method is useful to produce uniform particles with better functionality and targeted properties, and for designing new formulations for spray-dried powders typically produced in industrial setting. We also look into the use of rheology to assess different aspects of food formulations, processing, digestion, and sensory, in order to develop more practical tools for the industry. Several of our projects are directly funded by companies in Australia and overseas to solve practical challenges in their process and product development.
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Meeting location:
Science and Engineering Building, E8, Room 224, Lv2
Timeslot(s):
Wednesday 11:00
Research Area(s):
Process and reactor design of advanced technology: hydrogen generation, storage and utilisation and solar panel recycling
Research Overview:
My research group focuses on process optimization in chemical engineering, aiming to resolve practical engineering problems and improve the system efficiency. Our research extends from hydrogen generation, storage and utilization in steel industry to recycling of end-of-life solar panels. We work on the design of electrolyser for green hydrogen production, design of metal hydride-based hydrogen storage tank and design of operations of hydrogen-based ironmaking in steel industry in collaboration with Australian hydrogen industry and steel industry. We also work on the recycling of end-of-life solar panels. It is expected that there will be over one million tons of solar panels to be disposed of in 2035. We are developing advanced technologies to cost-effectively recycle the end-of-life solar panels. My team combines the experimental and numerical methods to design the high-efficiency system for these processes, and this prototype will be scaled up and applied in the real industry. Meanwhile, we help the industries map the advanced operating strategies and modify the design defects of their reactors. These close collaborations with the industry reinforce the link between academic expertise and industrial application in the field of chemical engineering.
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Meeting location:
(Meeting location: Science and Engineering Building, E8, Room Hilmer 316A, Lv3)
Timeslot(s):
Tuesday 15:00, Wednesday 13:00
Research Area(s):
Microstructured fluids, biomaterials, advanced imaging
Research Overview:
Unveiling the Hidden World of Microstructures: Shaping the Future of Sustainable Materials
Have you ever wondered how the seemingly simple products we use every day, from luxurious cosmetics and creams to advanced 3D printed materials, get their unique textures and properties? The answer lies in the fascinating world of microstructures - the tiny, intricate arrangements of molecules, particles, and polymers that dictate the behavior of fluids and materials.
In our lab, we're not just observing these microstructures, we're actively engineering them. Using cutting-edge imaging techniques, we explore the hidden world of fluid dynamics and material science, uncovering the secrets behind the structure and function of everything from biological systems to industrial products. Watch molecules as they self-assemble into complex networks, or track the flow of fluids through intricate channels. Our research provides a front-row seat to these phenomena, offering a unique perspective on the fundamental principles that govern the world around us.
These observations are the engine for innovation. By understanding the relationship between microstructure and material properties, we're developing new strategies to create sustainable alternatives to petroleum-based polymers and animal-derived products. From plant-based foods with improved textures to biodegradable plastics and advanced biomaterials, our research is paving the way for a more sustainable future.
If you're intrigued by the intersection of science, engineering, and sustainability, and you're eager to explore the unseen world of microstructures, our lab offers a stimulating and rewarding environment to pursue your research aspirations. Join us on a journey of discovery, where you'll not only contribute to groundbreaking scientific advancements but also make a tangible impact on society and the planet.
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Meeting location:
Science and Engineering Building, E8, Room 321 (let's meet in the lounge area in front of the lift on level 3)
Timeslot(s):
Tuesday 11:00, Wednesday 15:00
Research Area(s):
Biopolymers, bioorganic chemistry, nanomaterials, nanomedicine, drug delivery, 3D bioprinting
Research Overview:
The Wich Research Lab for Functional Biopolymers has its research focus in the area of macromolecular chemistry at the interface between nanotechnology and bioorganic chemistry. The main interest is in the chemical modification of natural biopolymers with the aim to engineer multifunctional and biocompatible materials for applications in drug delivery, nanomedicine, bio-catalysis and 3D printing. It is the goal to produce advanced nanomaterials with the potential to revolutionize personalized medicine and biocatalytic industrial processes.
Nature’s toolbox provides us with a variety of biopolymers, such as carbohydrates, lipids, or polypeptides. Our research group applies a variety of chemistry methods to produce functionalized nanomaterials in order to mimic biological properties, while maintaining biocompatibility and degradability. The resulting dynamic biohybrid materials can be formulated into nano- and microparticles for the transport and delivery of a wide range of therapeutic drugs, including therapeutic proteins, as well as DNA and mRNA.
We are looking for candidates who enjoy science and are excited about new challenges. Ideally, you are currently studying in one of these areas: (bio)organic chemistry, chemical engineering, material science, nanotechnology (but also, all neighbouring fields would be ok). Don’t worry, no specific pre-knowledge is necessary. You are a good match as long as you are enthusiastic about science and willing to learn! Don’t hesitate to get in touch with us if you have any questions 👍Visit our website for more details:
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Meeting location:
Science and Engineering Building, E8, Room 436, Lv4
Timeslot(s):
Wednesday 12:00
Research Area(s):
antimicrobial/antibacterial, anticancer, infectious diseases, polymer chemistry
Research Overview:
The escalating global issue of multidrug-resistant bacteria is now at a critical stage and urgently requires the development of new, effective and safe antimicrobial agents. Utilizing synthetic organic and polymer chemistry tools, my group focuses on the design of antimicrobial polymers and small molecules that mimic naturally-occurring antimicrobial peptides (AMPs) to combat these ‘Superbugs’. My group is developing novel, intelligent AMP mimics that can specifically respond to bacteria environment such as bacterial enzymes for targeted on-site activation, akin to a prodrug therapies. This platform technology could lead to commercial outcomes and can potentially be translated for use in anticancer applications.
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Meeting location:
Science and Engineering Building, E8, Room 335, Lv3
Timeslot(s):
N/A
Research Area(s):
polymer chemistry, polymers, nanoparticles, hybrid materials, emulsions
Research Overview:
My research group focuses on the design and synthesis of polymer and polymeric nano-objects for applications in a range of advanced and emerging technologies such as materials chemistry, nanotechnology and nanomedicine, as well as in more traditional fields such as paints and coating applications. One of the key concepts is structure control on the molecular and/or nano level – my team strives to develop and understand methods for synthesis of polymers of well-defined molecular structure (e.g. distribution of monomer units along the polymer backbone), as well as developing methods for synthesis of polymeric nano-objects of specific size and shape/morphology. Over the past few years, our research has expanded significantly into applied science such as e.g. pressure sensitive adhesives and energy applications. The foundations remain in fundamental science, but with significant links with applied science via collaborations with industry as well as academic collaborators.