Overview
Background
I am the Group Leader of Bio-inspired Materials Research at the Australian Institute for Bioengineering and Nanotechnology, The University of Queensland. My research focuses on transforming agricultural waste into innovative solutions for tackling plastic and food waste issues. My mission extends beyond research and into commercialisation. I am dedicated to fostering partnerships across industry, academia, community and government, utilising waste as a valuable resource for advancements in the environment, food and health sectors. My approach is clear: turning challenges into opportunities for a sustainable future.
I am a strong advocate for cultural diversity and equity, and support staff and students to grow as more effective leaders and create social good.
In recognition of my contribution to the field of nanomaterials engineering and research excellence, I have received several awards including one of the winners of AgriFutures Australia and growAG.Catalyst Program(2024), one of the Queelsnand Tall Poppy Award winners(2024), The Eight Australian Women Who Are Shaking up the World Of Science (Marie Claire, 2020), one of Australia’s Top 5 Scientists (ABC/UNSW, 2018), Queensland Women in STEM Prize- judges choice award (2017), Women in Technology Life Sciences and/or Infotech Rising Star Award (2016), AIBN Research Excellence Award (2016), a Class of 2014 Future Leader award and Best poster prize at the Australian Nanotechnology Network ECR Entrepreneurship workshop(2015).
Availability
- Dr Nasim Amiralian is:
- Available for supervision
- Media expert
Fields of research
Qualifications
- Doctor of Philosophy, The University of Queensland
Works
Search Professor Nasim Amiralian’s works on UQ eSpace
2009
Journal Article
Electrospinning of silk nanofibers. I. An investigation of nanofiber morphology and process optimization using response surface methodology
Amiraliyan, Nasim, Nouri, Mahdi and Kish, Mohammad Haghighat (2009). Electrospinning of silk nanofibers. I. An investigation of nanofiber morphology and process optimization using response surface methodology. Fibers and Polymers, 10 (2), 167-176. doi: 10.1007/s12221-009-0167-9
2009
Journal Article
Circular and Ribbon-Like Silk Fibroin Nanofibers by Electrospinning Process
Amiralian, N. and Nouri, M. (2009). Circular and Ribbon-Like Silk Fibroin Nanofibers by Electrospinning Process. Electrospun Nanofibers Research: Recent Developments, 279-295.
2007
Journal Article
Evaluation of reinforcement on the mechanical behavior of partially bonded fiber/matrix interface
Haghi, A. K., Sadrmomtazi, A., Bastani, A. Farjad, Amiralyan, N. and Haghi, R. K. (2007). Evaluation of reinforcement on the mechanical behavior of partially bonded fiber/matrix interface. Composite Interfaces, 14 (7-9), 647-668. doi: 10.1163/156855407782106465
Funding
Current funding
Past funding
Supervision
Availability
- Dr Nasim Amiralian is:
- Available for supervision
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Available projects
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Intelligent medical textiles
This research project advances our sustainable medical textiles stream to develop intelligent textiles that contain bioactive nanofiber and stimuli-responsive nanomaterials to detect viruses and bacteria and disinfect them. The visionary approach of this concept is based on the possibility of developing a new generation of medical textiles with synergistically combined chemically driven and light-assisted self-disinfection properties. The key in this research direction is the development of low-cost surface functionalities and textile design to enable sustainable industrial development.
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Biodegradable medical textile
Single-use plastic causes severe health and environmental impacts. It accounts for 25% of all waste generated by hospitals, which ends up in landfill and breaks down into tiny particles (microplastics) that cause severe health issues. Fossil fuel combustion to produce plastics is also a major contributor to air pollution-related deaths. This research aims to harness nature-derived materials to develop sustainable protective nonwoven fabrics for medical clothing such as PPE (face masks and medical gowns), filters (air and water), and wipes. Expected outcomes will transform the way we manufacture, use, and dispose of these materials.
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Smart and active packaging
The higher demand for healthy, safe and fresh products promotes the search for the development of active packaging systems to extend the food shelf life and monitor the quality of packed food. In active packaging, absorber or emitters are added to the packaging, which interacts with the inner environment of the package to enhance the shelf life of the food. This research project is built on the advancement of our biodegradable packaging materials research stream with a specific focus on food packaging. We will also investigate the effect of essential oils extracted from spinifex and other bush plants as active reagents in the development of active packaging.
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Sustainable biosensors
Conductive hydrogel is a 3D structural gel with high water content and electrically conductive materials e.g. metallic nanoparticles. This research aims to develop a reliable approach for making a new generation of conductive hydrogels that can serve as building blocks for bioelectronic devices in personalised healthcare and other bioengineering areas, including electronic skins, body matched antennas, and biosensors. This research focuses on the development of a system that demonstrates synergistic outstanding mechanical performance and electrical conductivity, which is currently a significant challenge in the field. Thus, this work is expected to create new paradigms for hydrogel materials fabrication with infinite applications.
Supervision history
Current supervision
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Doctor Philosophy
Nanoarchitectured anti-corrosion coatings for zinc-plated steel
Principal Advisor
Other advisors: Professor Yusuke Yamauchi, Dr Valentino Kaneti
Completed supervision
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2025
Doctor Philosophy
Dual-Functional Cellulose Nanomaterials for Antimicrobial and Low-Fouling Surfaces
Principal Advisor
Other advisors: Professor Alan Rowan, Dr Keng Chew
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2025
Doctor Philosophy
Sustainable antimicrobial coating materials for potential face mask application
Principal Advisor
Other advisors: Professor Mark Blaskovich, Professor Alan Rowan
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2024
Doctor Philosophy
Nanocellulose-based conductive polymer brush materials
Principal Advisor
Other advisors: Professor Alan Rowan, Dr Katrin Kockler
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2025
Doctor Philosophy
Nanoarchitecturing of Bimetallic Metal-Organic Frameworks and their Derived Materials for Sensing Applications
Associate Advisor
Other advisors: Professor Yusuke Yamauchi, Associate Professor MD Shahriar Hossain, Dr Valentino Kaneti
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2024
Doctor Philosophy
Sorption of Per- and Poly- Fluorinated Alkyl Substances from Different Wastewater Streams
Associate Advisor
Other advisors: Associate Professor Paul Jensen, Dr Bernardino Virdis, Associate Professor Ilje Pikaar
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2021
Doctor Philosophy
Cellulose Nanofibre and Nanopaper: Structure-property-processing Relationship and Green Surface Modification
Associate Advisor
Other advisors: Professor Lisbeth Grondahl, Professor Darren Martin
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2019
Doctor Philosophy
Reinforcement of Natural Rubber Nanocomposites using Lignocellulosic Biomass
Associate Advisor
Other advisors: Dr Pratheep Kumar Annamalai, Professor Darren Martin
Media
Enquiries
Contact Dr Nasim Amiralian directly for media enquiries about:
- Antimicrobial
- Biocomposites
- Biomaterials
- Circular economey
- Face mask
- Fibres
- Medical Textile
- Nanocellulose
- Packaging
- Plastic pollution
- Polymers
- Renewables
- Spinifex
- Valorising agricultural waste
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