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Institute for Frontier Materials Annual Report 2019

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Contents

Cover: IFM Associate Research Fellow, Dr Rossie Rao prepares battery materials for testing at IFM’s BatTRI-HUB battery prototyping facility.

deakin.edu.au/ifm

Part 1:3 2019 Year at a Glance4 Chair’s Report5 Director’s Report6 Our Vision, Our Mission7 2019 IFM Board Members

Research Case Studies8 Green insulation for the automotive industry9 New process for recycling rare earth metals10 Research aims to reduce micro-plastics in our waterways11 Engineers remake Aussie icon12 Breakthrough deals with overheating in electronic devices13 Seeking low-cost battery solutions14 Project seeks innovative designs for minerals industry15 Carbon fibres from Victorian lignite

Collaborative Centres Case Studies16 ARC Research Hub for Future Fibres18 ARC Training Centre in Alloy Innovation for Mining Efficiency (mineAlloy)19 ARC Training Centre for Future Energy Storage Technologies20 ARC Centre of Excellence for Electromaterials Science (ACES)21 Material design for future energy storage systems22 Innovative Manufacturing Cooperative Research Centre (IMCRC)

Part 2: Financial Reports, Grants and Publications25 IFM Financial Summary 201926 IFM Performance 2014 – 201927 Grant Holders and Their Projects32 Publications


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*headcount

2019 Year at a Glance


150 HDR students

Students from

30 countries

$16.5m research income

411 Journal Papers

233 Staff including

159 Researchers*

38 Student

completions


4deakin.edu.au/ifmInstitute for Frontier Materials Annual Report 2019

Throughout 2019, Institute for Frontier Materials (IFM) researchers continued to make outstanding advances in fields important to our future, including energy storage and circular materials design.As a result of successfully building on major research discoveries and advances in innovation, IFM attracted a total of $16.5M in 2019 from external research income.In a new $3M CRC-project, Professor Maria Forsyth, Prof Patrick Howlett and Dr Rob Kerr, with industry partners Calix and Boron Molecular, will create a new type of battery material that will substantially reduce the cost and environmental impact of high performance batteries. The same team were also successful in an ARC Linkage project on Next-generation solid-state batteries to drive an automotive revolution with Toyota Motor Corporation (Japan).Another collaborative project between Deakin, XEFCO and Proficiency Contracting was funded through the Innovative Manufacturing CRC (IMCRC). Dr Weiwei Lei, Dr Zhiqiang Chen and Dr Christopher Hurren, will develop a breakthrough commercial plasma deposition solution for the textile industry.The new ARC Training Centre in Green Chemistry – IFM researchers A/Prof Will Gates, A/Prof Alessandra Sutti and Dr Rangam Rajkhowa are key partners in this new ARC ITTC led by Monash University.IFM researchers were also successful in a number of prestigious regional, national and international awards. It was pleasing to see the world first ratings system for motorcycle clothing, developed by Dr Christopher Hurren and Dr Liz de Rome, awarded the Road Safety Award of the Federation Internationale de Motorcyclisme in Monaco in December 2019.

Chair’s Report

Dr Luhua Li received the David Syme Research Prize from the University of Melbourne for his work on Boron Nitride super materials and their commercialisation. Luhua’s research on Boron Nitride nanomaterials has helped to establish a start-up company (BNNT Technology Ltd), where he is the Chief Technology Officer.Dr Emily Kerr received a prestigious Victoria Fellowship which she will use to travel to Sweden and France to learn more about state-of-the-art approaches to diagnosis of early-stage chronic kidney disease.Professor Joselito Razal received an Endeavour Leadership award, which he used to visit Cornell University for five months to work in the area of ‘Fibres for energy, health, environment and electronics’.Our future challenge is to continue to grow IFM and its success and impact for Australia, while maintaining our commitment to excellence and relevance, and in the face of significant challenges and constraints affecting manufacturing related research in Australia.

Professor Julie OwensDeputy Vice-Chancellor ResearchChair, Institute for Frontier Materials Board

$3M CRC-P TO IMPROVE

BATTERY PERFORMANCE



Director’s Report

2019 was a great year for IFM. We earned more research income and published more quality papers than ever. But what I’m most proud of actually lies underneath these outputs.First, our lab safety performance rose markedly over the year and a special thanks to Suzanne Antonac for her support with this.Second, we trained and enthused 150 PhD students and 100 Post-doctoral researchers (all of our level A and B).Third, we built our new research pillar: re-designing materials for a circular economy. This pillar is really re-shaping our research.Our early career researchers have wholeheartedly embraced the challenge. Key projects we have seeded internally include: > re-designing laminated glass to enable it to be

separated and recycled,> creating new car interiors using waste wool,> making new non-woven products from waste carbon

fibres and> extracting valuable metals from spent batteries using

new separation techniques.Sustainability Victoria has joined us in our circular economy theme by funding two projects:> generating high-value nano-silicon from obsolete

solar panels, and > up-cycling of polyethylene with local partners

Qenos and GT Recycling.In 2019 we ran a regional circular economy innovation conference and facilitated a workshop on circular fashion. This enabled us to bring together researchers, industry, government and NGOs. We explored topics spanning e-waste, bio-char, packaging, metal alloys and textiles. This has sparked new relationships. A special thanks to Catherine McMahon for co-ordinating these activities.We were very pleased to launch our ARC storEnergy training centre, led by Professor Maria Forsyth. The

Centre will formulate the next generation of energy storage technologies – with a keen eye to ensuring circularity of material longevity, re-use and recycling. We submitted two bids for ARC Research Hubs and one bid for an ARC Training Centre. Two of these specifically targeted the pressing need for new materials to be sustainable and circular.In 2019 we also took delivery of two exciting new facilities. We took possession of a new small and wide-angle X-ray scattering facility that performs mini-synchrotron experiments. This facility will form the core of a new collaboration between Deakin and CSIRO, which we are calling InsitX – short for in-situ X-ray analysis.We also installed the first solid state metal 3D printer outside of the US. The technology will enable us to convert metal scrap into printed parts without melting. We will use it to create new circular streams of high value metal alloys and have already applied for a grant to modify it for use in space exploration, where material circularity is even more critical. The facility will be part of Deakin’s Circular Economy Factory.As for all the details, we hope you can easily find them in our annual report. If not please contact us.

Professor Matthew BarnettDirector, Institute for Frontier Materials


https://www.youtube.com/watch?v=TYHazharr30&feature=youtu.be

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Our VisionTo lead and inspire innovations in materials science and

engineering that have a transformational benefit to society.

Our MissionTo create and translate knowledge at the frontier of materials

science for globally raised standards of living by:> Re-designing materials for a circular economy

> Imparting materials with extraordinary functionalityThrough excellence in research quality, translation,

training and research culture.


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Professor Julie Owens

Chair and Deputy Vice-Chancellor Research

Professor Maria Forsyth

Associate Director, Institute for Frontier Materials

Professor Saeid NahavandiDirector, Institute for Intelligent Systems

Research and Innovation

Dr Leonie WalshExternal

Independent Director

Ms Genevieve ReidDirector, Deakin Strategic Partnerships – Research

Professor Seeram Ramakrishna

External Independent Director

Professor Matthew BarnettDirector, Institute for

Frontier Materials

Professor Karen Hapgood

Executive Dean, Faculty of Science, Engineering

& Built Environment

Professor Gordon Wallace


Dr Kathie McGregorSenior Representative,

CSIRO

Professor Sybrand van der Zwaag


Mr Francois Souchet External

Independent Director

deakin.edu.au/ifmInstitute for Frontier Materials Annual Report 2019

2019 IFM Board MembersThe IFM Board is responsible for advising on the external opportunities for research, development and commercialisation activities of IFM.


8deakin.edu.au/ifmInstitute for Frontier Materials Annual Report 2019 Re-designing materials for a circular economy

RESEARCH CASE STUDIES

Green insulation for the automotive industry

“Our aim was always to do something that has an impact for industry and for people – we really want to see an improvement in people’s lives and the environment.” Dr Maryam Naebe

Dr Maryam Naebe (right) and Dr Zengxioa Cai preparing non-woven felt for testing.

The insulating benefits of wool could soon be felt under the bonnets and in the interior of our cars, thanks to research by IFM fibre scientists.

With a grant from Ford Motor Company, the team at IFM, led by Dr Maryam Naebe, has developed a new wool-based insulation textile for car interiors. The work helps address the automotive industry’s need for affordable, sustainable alternatives to synthetic, petroleum-based plastics as well as providing a potential new market for waste wool. With the demand for better fuel economy and introduction of tighter environmental regulations, car manufacturers around the world are seeking to replace synthetic car interiors with lighter, natural fibre options. Ford has been a leader in this area. The company was the first to incorporate soybean oil into polyurethane foam for seat cushions, backs and headrests, and Ford vehicles contain more than 10 plant-based materials developed within their labs. However, most car insulation is currently made using petroleum-based microfibres.Wool’s unique fibre structure gives it inherent thermal and acoustic insulation properties, which makes it a very promising candidate for sustainable insulation. The IFM researchers went through a raft of testing methods and fibre mixing variations before selecting a final product by using blended waste and virgin wool insulated fibres covered with a thin nonwoven fabric via needle-punching.

A major challenge for the project was how to develop a replacement with the same sound absorption, thermal resistance and air permeability benefits as a synthetic car insulator. The new material meets sound and thermal absorption requirements for certain automotive applications. The prepared wool felt is an environmentally-friendly insulating material that not only greatly reduces the waste of end-of life vehicles but also makes the most of available natural resources. It has similar sound absorption, thermal resistance and air flow qualities to the current synthetic textile options, while the wool also offers the added benefits of being naturally odour-resistant and flame retardant.

The outcome of this work will provide environmentally superior insulation material that’s perfectly suited for the emerging era of affordable, sustainable transportation.The researchers are now looking to scale up and continue working with Ford on testing to refine the treatment process.


9deakin.edu.au/ifmInstitute for Frontier Materials Annual Report 2019 Re-designing materials for a circular economy

New process for recycling rare earth metals

Dr Cristina Pozo-Gonzalo leads a collaborative research team investigating the use of ionic liquids for rare earth metal recovery.

Rare earth metals (REMs) are essential for modern technology applications. Without them our mobile phones, computers and electric vehicles would cease to function.

By 2035 the demand for rare earth metals is expected to grow from today’s figure of 150,000 tonnes to approximately 400,000 tonnes, creating severe pressure on global supply chains. Current recovery methods of REMs are energy intensive (e.g. high temperatures about 1000oC) and involve large amounts of corrosive materials. Therefore, a cleaner and simpler way of recovering REMs is urgently needed.IFM researchers together with scientists at Spain’s Tecnalia research and innovation hub have developed an innovative process, using environmentally friendly chemicals, to improve REM recovery methods. After separating the metals from their end-of-life product, the team, led by Dr Cristina Pozo Gonzalo, use the ionic liquids (salt-based systems) to recover the rare earth metals from the resulting solution using a process of electrodeposition. This new method for recovering REMs has great potential and minimises the generation of toxic and

Highlight Publication: Water-Facilitated Electrodeposition of Neodymium in a Phosphonium-Based Ionic Liquid. L. Sanchez-Cupido, J.M. Pringle, A.L. Siriwardana, A. Unzurrunzaga, M. Hilder, M. Forsyth, C. Pozo-Gonzalo. 2019 J. Phys Chem. Lett. 10 (2), 289-294.

harmful waste. They are also aiming for a method that can easily be implemented widely across the world. Dr Pozo-Gonzalo said REMs were among the top critical raw materials identified by the European Commission, Geoscience Australia, and United States Department of Energy.

“The efficient recovery of REMs from recycled materials is becoming increasingly important, given that only about 3 to 7 per cent of REMs are currently recovered from end-products because of technological difficulties,” she said.

The IFM/Tecnalia work addresses a key knowledge gap in the REM recycling process. It is an important early step towards establishing a clean and sustainable processing route for REMs and alleviating the current pressures on these critical elements. The team is working on several projects, focusing on widening the methodology to apply to other valuable metals that are used in energy storage systems.


10deakin.edu.au/ifm

Research aims to reduce micro-plastics in our waterways

Highlight Publication: Nano/microplastics in water and wastewater treatment processes – Origin, impact and potential solutions. M. Enfrin, L.F. Dumee, J. Lee. 2019 Water Research 161, 621–638.

Work by IFM and University of Surrey researchers has shown that wastewater treatment processes break down tiny pieces of plastic even further, which both reduces the performance of the treatment plants and also affects water quality.While micro-plastic pollution has been studied before, until now it has not been understood how the plastics interact with water and wastewater treatment processes. The new research by PhD student Marie Enfrin and Dr Ludo Dumee from IFM and Dr Judy Lee from the University of Surrey shows that water and wastewater treatment processes break micro-plastics down even further into nano-plastics, which pose a threat to aquatic ecosystems and human health. Their analysis suggests that new strategies are needed to limit the amount of nano and micro-plastic in waterways and reduce threats to the ecosystem.About 300 million tons of plastic is produced globally each year, with up to 13 million tons released into rivers and oceans, contributing to a predicted cumulative amount of 250 million tons of plastic by 2025. The small size and high specific surface area of micro and nano-plastics makes them easy to ingest by birds and

Plastic waste in rivers and oceans is a common sight in many areas, but even worse is the plastic we cannot see – micro and nano plastics.

Institute for Frontier Materials Annual Report 2019 Re-designing materials for a circular economy

marine animals, where they can reach toxic levels. Their small size also makes it easy for particles to travel along water and wastewater treatment processes. At high concentrations the micro particles can affect the performance of water treatment processes by clogging up filtration units and increasing wear and tear on materials.However, inadequate analytical techniques make it difficult to detect their presence in treatment systems. Ms Enfrin and Dr Dumee are trialling advanced characterisation systems to improve detection. The team is also evaluating the impact of micro and nano-plastics on the performance of commercial membranes to specifically design new membranes for better fine matter filtration, by altering the surface properties of the membranes.


11deakin.edu.au/ifm

Engineers remake Aussie icon

Dr Matt Dingle (left) and Dr Matthias Weiss with samples made using the unique Formflow bending technique.

The Prefab 21 house constructed using an innovative modular building system.

A small start-up formed by IFM senior research fellow Dr Matthias Weiss and Carbon Revolution co-founder, Dr Matt Dingle is bringing a step change to the future of corrugated iron.

The young company, FormFlow, has patented its innovative process and is operating from Deakin’s ManuFutures innovation hub.The steps to the new process began with IFM Honorary Professor John Duncan and his late brother, Jim Duncan who published the geometric theorems, governing the folding of curved surfaces in 1992. Using modern, computer aided design (CAD) technology, John Duncan, together with Drs Weiss and Dingle went on to produce the first scientifically designed forming system to fold corrugated sheet and make the FormFlow bend.The stand-out feature of FormFlow is its potential to apply revolutionary technology on a broad scale. It opens a whole range of possibilities for the structure of any building – offering new ways to form, assemble and manage building projects.Unlike vehicle production, which has become fully automated, using robotic production lines to limit construction errors and waste, the building industry is still relatively low tech. The FormFlow technology will potentially help builders construct a new building with higher performance at a fraction of the cost.In a recent project known as ‘prefab21’, FormFlow, together with Deakin University Chair in Architecture, Professor James Doerfler and 14 undergraduate

students has developed a modular building system that lends itself to new prefabrication technologies based on those used in the automotive industry. A house built with the modular building system will be installed at Samaritan house in Geelong to provide temporary shelter for homeless men. FormFlow bends are structurally stiff and strong, airtight, with an attractive seamless appearance. The process eliminates the need for capping and improves energy efficiency and fire resistance. The bends can be made at a number of angles, with the 90-degree angle of particular interest to builders.

Institute for Frontier Materials Annual Report 2019 Imparting materials with extraordinary functionality


12deakin.edu.au/ifm

Deakin researchers have made a breakthrough discovery in the area of thermal conductivity and heat regulation, which will pave the way for the next generation of foldable phones, wearable technology and miniaturised electronics.

Dr Qiran Cai (L) and Dr Luhua Li discovered that atomically thin boron nitride had a very high thermal conductivity which could help cool electronics for optimum performance.

Breakthrough deals with overheating in electronic devices

IFM researchers have made a breakthrough discovery in the area of thermal conductivity and heat regulation, which will pave the way for the next generation of foldable phones, wearable technology and miniaturised electronics. Dr Luhua Li and Dr Qiran Cai partnered with researchers from Northern Ireland and Japan to pioneer development of a highly thermally conductive and chemically stable material to help deal with overheating issues in modern devices. Heat management is a critical issue in miniaturised modern devices and most people will have experienced devices overheating, e.g. when a phone gets hot or a laptop’s internal fan starts whirring madly. With emerging technology such as foldable phones, micro-machines and wearable devices, thermal cooling has become critical for the performance, reliability, longevity, and safety of various products. Scientists are striving to come up with alternatives to aluminium and copper, which are conductive and potentially cause short circuit problems. Electrically insulating materials such as diamond and boron arsenide have been shown to work, but they are too rigid and inflexible, as well as too expensive for mainstream use.

By taking a chemical compound known as boron nitride (BN) and shaving it down to an atomically-thin level, the researchers were able to give the material the desired flexibility while dramatically increasing its thermal conductivity and cooling capabilities. Atomically thin BN has better thermal conductivity than most semiconductors and insulators, along with low density, outstanding strength, high flexibility and stretchability, good stability, and excellent impermeability, making it a promising material for heat dissipation in next generation devices. This is a fundamental breakthrough, and with time and further research it will help to open up the boundaries of what’s possible in electronic devices – particularly as the trend in next generation electronics will most likely need to be flexible.

Highlight Publication: High thermal conductivity of high-quality monolayer boron nitride and its thermal expansion. Q. Cai, D. Scullion, W. Gan, A. Falin, S. Zhang, K. Watanabe, T. Tanaguchi, Y. Chen, E. Santos and L. Li. Science Advances 5 (6), eaav0129.

Institute for Frontier Materials Annual Report 2019 Imparting materials with extraordinary functionality


13deakin.edu.au/ifm

Seeking low-cost battery solutions IFM researchers are working to create a new type of battery material that will reduce the cost and environmental impact of high performance batteries.

Working with industry partners Calix Pty Ltd and Boron Molecular, the team are exploring the combination of their newly developed alternative battery materials with more readily available traditional compounds produced using a new processing technology. The new three-year project has received $3 million from the Federal Government’s Cooperative Research Centre Projects (CRC-P) program, which supports short-term industry-led collaborations in new technologies, products and services. Professor Maria Forsyth, who leads the IFM team, said that energy storage was a growing area of research, but the challenge was to develop manufacturing capability in Australia. “There is a global search for safe, low cost, high capacity, high performing batteries given the demand for high performance energy storage and electric vehicles,” Professor Forsyth said. “The challenge for Australia is to develop a sustainable battery manufacturing industry that has global reach through process innovation.”

IFM is ideally placed to lead the research, with its Battery Technology Research and Innovation Hub (BatTRI-Hub) – a world-class research and innovation centre focused on advanced battery prototyping and the commercialisation of energy storage technologies. The team will explore the use of Calix’s patented technology to produce customised, micron sized, nano-electroactive materials for battery anodes and cathodes. These will be integrated with optimised ionic electrolytes, developed with Boron Molecular, to make up to 10 kWh battery pack prototypes. The project is a first for battery research in Australia, in its use of high rate processing technology with Australian materials. The materials will also have capacity to go into high performance supercapacitors which store charge like a battery and can dispense that charge very quickly. The project will involve a field trial of the battery packs, including solar applications linked to small solar PV systems and the Deakin Microgrid, being developed at Deakin’s Waurn Ponds campus.

Professor Patrick Howlett (L) and Dr Rob Kerr - pioneering the use of high rate processing technology with Australian materials.

Institute for Frontier Materials Annual Report 2019 Industry Partnerships


14deakin.edu.au/ifm

The partnership started in a small way with two short Innovation Connections grants. Some highly encouraging results were a springboard for a successful CRC-P application. This $3.9 million project is championed by Callidus CEO Gary Lantzke and involves IFM researchers, Associate Professor Daniel Fabijanic, Professor Matthew Barnett and Dr Santiago Corujeira Gallo, and also a team from CSIRO, and mining companies, Murrin Murrin Operations and Newcrest. The CRC-P assessors praised the strong expertise of the team and commented that the project demonstrated the sort of problem-solving initiative that this grant scheme was designed to foster.The severe conditions of erosion and high temperature acid corrosion in hydrometallugical reactors test the endurance of even the most advanced alloys. Through novel component design and surface modification technologies, the project is poised to deliver a doubling of component life, improving the efficiency of the process and potentially saving the industry millions of dollars in lost production time. Lead IFM researcher, Associate Professor Fabijanic reflects on the development of this collaboration, “This is a great example of letting a partnership naturally develop. “First, we assisted Callidus with insight into a process they had been independently developing over a few years. “Next, I introduced a new surface modification concept, which they could immediately adopt using their current capabilities.“It was a real highlight to see CEO, Gary Lantzke’s eyes light up at the possibilities of this new technology angle.

“Callidus is very open to new ideas, and so far these new concepts are working well. The benefits and learning has been two-way, which is how a partnerships should be.”

Already the technology is being adopted commercially with clear benefits according to Gary Lantzke.“The partnership we have developed with Deakin is a true win, I hope for both teams. Innovation although a bit overused today is at the core of our DNA as a company. “What happened when Deakin became a resource has been truly magic. Almost every trial we have placed has performed exceptionally well and to date two new products have been born.”


A partnership between IFM and WA company Callidus Welding Solutions is delivering novel solutions to address erosion and corrosion of components used in mineral processing.

Project seeks innovative designs for minerals industry

(Above) Cross-sectional microstructure of metal/ceramic coating on Ti alloy. (Below) High magnification images show dendritic titanium nitride structure (dark regions) in the inter-dendritic titanium matrix (grey regions) along the thickness of surface modification.


15deakin.edu.au/ifm

Carbon fibres from Victorian ligniteVictorian brown coal shows promise as a naturally occurring precursor material for carbon fibre.

Carbon fibre exhibits outstanding specific strength and modulus, almost four times that of steel, making it one of the strongest materials on the planet today. Carbon fibres are now being used commercially in structural, light-weight composites for a wide range of industries such as aerospace, automotive, bicycles, oil and gas, clean energy and sporting goods, where they are replacing traditional materials such as steel and aluminium. Carbon fibres are also starting to be used in the automotive industry, but greater market penetration is limited by cost. Currently, most carbon fibres are made from polyacrylonitrile (PAN) which is an expensive petroleum-based polymer contributing to more than 50% of the cost.Victorian brown coal or lignite, with its inherently low nitrogen, low sulfur and low ash content, is arguably the cleanest coal in the world. It has lower levels of these ‘impurities’ than most forms of biomass. Since impurities often become concentrated in the product materials, this makes Victorian brown coal a near ideal naturally occurring precursor material for all sorts of carbon products. It is also very cheap due to its massive accumulation in large deposits that are already operational and readily mined by open cut methods. In a collaborative project with Monash University, led by IFM’s Associate Professor Minoo Naebe, researchers are investigating the production of low-cost carbon fibres using precursors derived from Victorian lignite. The project involves a team at the School of Chemistry at Monash University with expertise in chemical transformation and fractionation of Victorian lignite, and the IFM team at Carbon Nexus with expertise in


production and characterisation of carbon fibres. Carbon Nexus is a globally unique carbon fibre and composite materials research facility, which houses an industrial pilot and research scale carbon fibre processing line, a precursor fibre spinning line and composite manufacturing capabilities. Carbon fibres containing up to 40% lignite have been produced using two of the extract materials using the wet-spinning technique and subsequent thermal stabilisation and carbonisation. Based on previous experience, the team is confident that, with further optimisation, carbon fibres with higher lignite content could be produced to meet the cost and performance requirements of the automotive industry.Funding for this project is provided by Australian Carbon Innovation (ACI) and Australian National Low Emissions Coal Research and Development Ltd (ANLEC R&D).

Key Messages> Widespread commercial use of carbon fibres in the

automotive industry requires a lower cost alternative to the current fibre precursor, polyacrylonitrile (PAN)

> Victorian lignite is an inexpensive source of suitable carbon

> This project involved a preliminary investigation of carbon fibre production using four different extracts derived from Victorian lignite

> The project successfully produced carbon fibres containing up to 40% Victorian lignite with PAN

> Further research is underway to increase the proportion of Victorian lignite and to improve the strength of the carbon fibres.


16deakin.edu.au/ifm

ARC Research Hub for Future Fibres Novel fibres for multiple applications

Development of fibres for value-added applications is one of the key themes of the ARC Research Hub for Future Fibres. Recycled denim, for example, could have surprising applications in water filtration and battery technology. Smart fibres, such as those incorporating MXene, with high stretchability and conductivity, could be used as sensors in clothing.Hub researchers, Associate Professor Nolene Byrne and PhD student Beini Zeng, have discovered how to dissolve denim and manipulate the remains into an aerogel – a low density, highly porous material with a range of potential uses including water filtration and use as a separator in advanced battery technology. The researchers dissolved the denim using ionic liquids (a natural solvent) and when they reformed the cellulose into an aerogel, found something they didn’t expect – a gel with a unique porous structure and nanoscopic tunnels running through it. By altering the production conditions the shape and morphology can be controlled, allowing the aerogel properties to be tuned for specific applications.

Aerogels are a class of advanced materials with very low density and a highly porous structure which allows the passage of gas and liquid, sometimes referred to as ‘frozen smoke’ or ‘solid smoke’. Due to these properties they make excellent materials for bio-scaffolding, drug delivery, absorption or filtration.In another project, Hub researchers Professor Joselito Razal and PhD student Ken Usman, working with IFM colleague Dr Shayan Seyedin and Professor Yury Gogotsi’s group at Drexel University in the United States, are engineering the next generation of wearable devices. Their innovative fibres could one day allow our clothes to track our movements.The researchers use an unusual material known as MXene to produce the conducting and stretchable fibres. They use a wet-spinning technique to produce the fibres which show both conductivity and high stretchability. Using a commercial-scale knitting machine, they knitted MXene-polyurethane composite fibres into a one-piece elbow sleeve which can track various movements of the wearer’s elbow.

Institute for Frontier Materials Annual Report 2019 Collaborative Centres

Associate Professor Nolene Byrne and PhD student Beini Zeng discovered some surprising properties when they reformed the cellulose from dissolved denim.

COLLABORATIVE CENTRES CASE STUDIES


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Researchers use a lab-scale wet spinning line to produce the MXene fibres.

Endeavour Fellowship for Joe

deakin.edu.au/ifmInstitute for Frontier Materials Annual Report 2019 Collaborative Centres

Highlight Publications:Circular textiles: closed loop fiber to fiber wet spun process for recycling cotton from denim, Y. Ma, B. Zeng, X. Wang, N. Byrne, ACS Sustainable Chem Eng (2019), 7, 11937-11943Highly conductive Ti3C2Tx MXene hybrid fibers for flexible and elastic fiber-shaped supercapacitors, J. Zhang, S. Seyedin, S. Qin, Z. Wang, S. Moradi, F. Yang, P.A. Lynch, W. Yang, J. Liu, X. Wang, J.M. Razal, Small (2019), 15, 1804732

The research shows fundamental insights into the behaviour of MXene in elastomeric composites and presents strategies to achieve MXene-based fibres and textiles with strain sensing properties suitable for applications in health, sports and entertainment (such as VR games and simulations).The smart fibres could offer wearable alternatives to bulky and hard-to-wear devices. The team is now investigating how to produce the fibres in larger quantities and improve their performance before testing them in real life applications.This work is a small sample of the outcomes from the ARC funded Future Fibres Hub which works with five industry partners on a wide spectrum of fibre technologies. The Hub’s aim is to develop next-generation solutions for reducing our environmental footprint and improving public health and wellbeing. The Hub, which funds 11 researchers and 7 PhD students, is into its 4th year of operations and will wind up in mid-2021.

Hub Deputy Director, Professor Joe Razal spent the last four months of 2019 in the US on an Endeavour Executive Leadership Award. Joe visited Cornell University, where he worked in the area of ‘Fibres for energy, health, environment and electronics’ with A/Prof Juan Hinestroza. Juan leads the Textiles Nanotechnology Lab at Cornell where research is focused on the interface between the traditional field of fibre and textile science and the emerging field of nanoscale science. Through this novel approach his team explore new pathways for creating multifunctional fibres via manipulation of nanoscale phenomena. While in the US, Joe also visited other universities including: Drexel University, Tufts, UT Dallas and Austin, University of Houston and Rice University. He also made contacts with potential future industry partners including Columbia Sportswear, Lycra Co and Google.


18deakin.edu.au/ifm

ARC Training Centre in Alloy Innovation for Mining Efficiency (mineAlloy)New alloy promises longer life for components

One of Keech’s ground engaging tools being instrumented for a heat treatment trial. The temperature of the part is recorded during the heat treatment to understand the process and develop a material suitable for the company’s heat treatment facilities.

The ARC Training Centre in Alloy Innovation for Mining Efficiency (mineAlloy) is training the next generation of innovators to design highly customised, long-life, wear resistant components for the mining industry.One of mineAlloy’s partners is Bendigo company, Keech Castings Australia Ltd. Keech has worked with researchers at the Institute for Frontier Materials since 2013 when the company collaborated in a PhD project, which resulted in a new type of steel for some of its ground engaging tools – used in the mining industry for excavation and loading.This project set the scene for the company to become a partner in mineAlloy.The project with Keech, which started in 2018, involves development of a revolutionary new type of steel for ground engaging tools. After a successful pilot scale casting and heat treatment trial, the team is now preparing a new trial with an improved version of the alloy, aiming to produce a batch of ground engaging tools for a field trial at a local mine in 2020.Keech has pioneered steel wear solutions in ground engaging tools and this project is just one example of how the mineAlloy centre is bringing together the combined experience of researchers and industry to address real world problems. The industry partners cover the mining product supply chain and provide the centre with extensive knowledge about metal processing, component design, in-field conditions and access to commercial facilities.The researchers and industry partners are also working on other projects, while at the same time training the next generation of innovators to solve industry problems. These projects include development of a wear sensor, casting of parts with new materials and lightweighting of mining equipment and machine components.Future projects will also investigate the design of materials that are easier to recycle and reuse and the design of processes that can use waste streams.mineAlloy comprises three university partners: Deakin University, University of Queensland, and Monash University and seven core industry partners: Keech Castings Australia; IXL Metal Castings; Cast Bonding Australia; Gekko Systems; Weir Minerals; Trelleborg Engineered Systems; and Bradken; and supporting partners Newcrest Mining; Austmine; METS Ignited Australia; Applus; and Australian Foundry Institute.For more information visit: minealloy.com.au



http://minealloy.com.au

19deakin.edu.au/ifm

ARC Training Centre for Future Energy Storage TechnologiesDeveloping future energy storage solutions


A new ARC Training Centre in Future Energy Storage Technologies (storEnergy) is forging ahead with research to address Australia’s future energy needs. The centre, which is led by IFM’s Professor Maria Forsyth, was officially launched in December 2019.With support of $4.4 million from the Australian Research Council, storEnergy is a collaboration between research partners Deakin, Monash University, University of Melbourne, Queensland University of Technology, University of South Australia and CSIRO; and industry partners Boron Molecular, DST Group, SupraG Energy, Calix Ltd, Sensorplex, Ionic Industries, Ciditec, Sentek, M Brodribb Pty Ltd, and Raedyne Systems.Working closely with the industry partners, researchers will design and manufacture new energy storage devices and components, including advanced Li-ion, super capacitors, and solid state Li and Na batteries, with improved rate capability, capacity and safety.

The centre will also train a new generation of industry-ready graduates, with an initial 15 PhD students. Professor Forsyth said the centre would unearth knowledge and create intellectual property in advanced energy materials, batteries and battery-control systems that will help small to medium-sized businesses play a world-leading role to advance and produce new storage technologies.

“The facilities, processes and partnerships we have in place will equip the next generation of researchers and the energy technology workforce with the skills needed to drive innovation, exploration and investigation,” said Professor Forsyth.

storEnergy director, Professor Maria Forsyth, Senator for Victoria, Sarah Henderson, ARC CEO, Professor Sue Thomas, and Deakin University Vice Chancellor Professor Iain Martin at the official launch of the ARC Training Centre.


20

ARC Centre of Excellence for Electromaterials Science (ACES)The ACES network of members and collaborators is substantial, creating a significant global reputation. These international linkages are illustrated through our publications. In 2019, 102 journal articles (52%) were published with international co-authors, and 626 articles (54.7%) since 2014. The articles published in 2019 have been cited 579 times (54 citing countries). ACES articles published between 2014 and 2019 have received 21,899 cites from 11 citing countries (SCIVAL, Scopus data 6.1.20).

2019

102Journal articles

52%were

published with international co-authors

ACES

626

Articles published between

2014 & 2019have received

21,899cites from

11countries

Cited

579 times

54citing

countries

2014 – 2016

626Total journal

articles

54.7%since 2014

with international

authors

deakin.edu.au/ifm20Institute for Frontier Materials Annual Report 2019 Collaborative Centres


21

Material design for future energy storage systems

deakin.edu.au/ifm

The team, led by ACES Associate Director, Professor Maria Forsyth, research fellow Dr Fangfang Chen and Professor Patrick Howlett, are working on the smart design of solid-electrolyte interfaces with the aim of producing cheaper Sodium ion batteries using ionic liquid electrolytes. In work published this year, they combined two types of anions in the electrolytes – one to produce satisfactory ionic conductivity, and the second to help form a solid electrolyte interphase layer to support longer stable battery charging and discharging. They successfully demonstrated the strategy by both experiment and simulation. Dr Chen leads the modelling team working on novel electrolyte materials. Their work provides in-depth knowledge and understanding about electrolyte interfaces. Dr Chen’s modelling has revealed how the interfacial nanostructures of ionic liquid electrolytes affect a battery’s electrochemical behavior, as well as explaining the role of cations, salt concentrations, and other factors. This modelling provides guidance and strategies for the rational design of batteries. The group also collaborates with other battery specialists and researchers, both nationally and internationally, in the field of solid-state polymer electrolytes. They collaborate with Prof Michel Armand and Dr. Heng Zhang at CIC Energigune working on new functionalized anions to target specific problems during development of solid polymer electrolyte. Dr Chen and IFM research fellow, Dr. Xiaoen Wang have highlighted the use of a specific type of commercially available polymer, polymerized ionic liquids, as solid electrolytes for lithium metal batteries. Their work has attracted great interest worldwide and has been cited and reported by many online media outlets.

Highlight Publication:Poly(Ionic Liquid)s-in-Salt Electrolytes with Co-coordination-Assisted Lithium-Ion Transport for Safe Batteries. Xiaoen Wang, Fangfang Chen, Maria Forsyth et al. (2019) Joule, 3, 1-16.

IFM researchers at the ARC Centre of Excellence for Electromaterials Science (ACES) are designing advanced materials for use in future energy storage devices based on experimental research and molecular simulations. They are focusing on three key areas – solar fuels, thermal energy conversion and energy storage.


IFM PhD student Dmitrii Rakov uses simulation modelling to help guide future battery design.


22deakin.edu.au/ifmInstitute for Frontier Materials Annual Report 2019 Collaborative Centres

Innovative Manufacturing Cooperative Research Centre (IMCRC)

The team has now expanded to 11 full time members with additional resources through Deakin’s Institute for Intelligent Systems Research and Innovation (IISRI) to focus on Industry 4.0 initiatives.Carbon Revolution is the only company globally to have successfully developed and manufactured single piece carbon fibre automotive wheels to Original Equipment Manufacturer (OEM) quality standards with commercial adoption across several major OEM models.Carbon fibre wheels have a range of benefits over wheels constructed from traditional materials, including improved vehicle efficiency, enhanced vehicle performance, increased range for electric vehicles, improved noise, vibration and harshness performance, and aesthetic improvements. With a target weight reduction of up to 50% per wheel, carbon fibre wheel technology provides a very significant reduction in rotating unsprung weight.With Carbon Revolution based onsite at the Deakin Waurn Ponds campus, the Deakin team is able to be embedded within their facility, fully immersed within engineering, development and process engineering teams. This close working relationship with the industry partner provides the opportunity for the team to be aligned with the latest priorities and challenges with the

The Deakin/Carbon Revolution collaboration project facilitated through the Innovative Manufacturing CRC (IMCRC) continues to make progress across a number of areas.

manufacture of carbon fibre wheels. This gives us the best of both worlds, says project manager Rod Macaulay.

“We have access to IFM’s world class material development facilities and expertise, while working side by side with the industry partner.”

The project focuses on the ongoing development of Carbon Revolution’s material and process technologies, in order to ensure that Carbon Revolution retains and extends its leadership position in high performance carbon fibre wheels. The project scope is quite vast with research and development covering resins, carbon fibre, resin transfer moulding, surface finish, preform optimisation, non-destructive testing, thermal management and industry 4.0 best practice. This requires a very diverse team from a variety of different backgrounds. Overall goals of this project are around material and process improvements, improved quality and lower cost for a high volume manufactured carbon fibre composite product. The project has already provided some incremental improvements with a number of longer term initiatives still under development. Now past the half way mark of the original development plan, expected completion date is June 2021.

Some of the team working on the Carbon Rev/Deakin IMCRC project, overlooking the Carbon Revolution factory at Waurn Ponds – Dr Akhila Mukkavilli, Dr Kathleen Beggs, Mr Yao Ding and Dr Kiran Patil


23

Financial Reports, Grants and Publications Annual Report 2019

Part 2:

deakin.edu.au/ifmInstitute for Frontier Materials Annual Report 2019 24

25 IFM Financial Summary 201926 IFM Performance 2014 – 201927 Grant Holders and Their Projects32 Publications

Financial Reports, Grants and Publications

Contents

Part 2:


25deakin.edu.au/ifm

IFM Financial Summary 2019Financial Summary for Period Ended 31 December 2018 Actual 2019 Actual

Income $ $

Research Income 13,450,981 16,455,810

Other Income 581,385 769,968

Research Allocation/ University Contribution 19,564,649 20,501,275

Total Income 33,597,015 37,727,054

Employment Costs

Academic Salaries 16,794,053 18,885,990

General Salaries 6,326,019 7,083,819

Other Employment Costs -47,935 79,673

Contractors 3,719 176,787

Total Employment Costs 23,075,856 26,226,270

Non Salary Expenses

Buildings & Grounds Infrastructure Costs 294,119 231,471

Communication/Advertising, Marketing & Promotions 119,588 134,060

Consumables 1,323,894 1,736,612

Depreciation & Amortisation 3,252,610 3,157,114

Equipment – Repairs, Maintenance & Other Costs 1,462,682 1,918,573

Other Costs* 1,094,879 1,329,201

Professional, Legal and Consultants 18,906 37,891

Staff Recruiting, Training & Other/Library Information Resource Expenses 392,670 494,020

Student Expenses 1,458,810 1,367,742

Travel, Catering & Entertainment 1,103,000 1,094,100

Total Non Salary Expenses 10,521,159 11,500,784

Surplus/(Deficit) – –


*includes contributions to other universities, IT, project costs, non salary recoverable, fleet management.


26deakin.edu.au/ifm

HDR Student Load (Equivalent Full Time, 2014 – 2019)

*Publications (2014 – 2019)

2019 Grant Applications Awarded

HDR Student Completions (Equivalent Full Time, 2014 – 2019)

2014 2015 2016 2017 2018 2019

144.0 143.1 143.1 139.3 150.1 158.7

2014 2015 2016 2017 2018 2019

170.0 162.3 190.1 212.5 251.5 302.8

2014 2015 2016 2017 2018 2019

23.0 30.0 30.0 33.0 29.0 38.0

Grants Amount Awarded

Reportable – Category 1 $933,644

Reportable – Category 2-4 $7,053,603

Total $7,987, 247

IFM Performance 2014-2019


The amount awarded represents the amount awarded over the total life of the project as initially communicated by the funding agency.

*ACG (Australian Competitive Research Grants – Category 1) is the term used to describe a group of some 70 research grant schemes to which all universities can apply and where awards are based on merit of the application and the research team. The ARC and NHMRC are two of the major funding bodies included in this list.

*Other public (Other Public Sector Research funding – Category 2) is government funding, Federal or State, from schemes not included in the ACG group and not necessarily determined through a competitive process; it includes contract research and research-related consultancies.

*Industry (Industry and Other Funding – Category 3) includes all research funding from industry, international sources, donations, bequests and foundations, and Higher Degree by Research fee income for domestic and international students.

*CRC (Category 4) is a university’s research income from Cooperative Research Centres excluding their own contribution. Note: CRC income is based on financial year results.

Category 2Government sector R&DCategory 3Industry & other R&D

Category 4Co-operative research centres R&D

Category 1Australian competitive grants R&D

2019


27deakin.edu.au/ifm

Australian Research Council

Australian Research Council Discovery

Grant Holders and Their Projects

Prof M Barnett, Dr P Lynch, Dr A Stevenson, A/Prof M Fivel

Real-time imaging of crystal strengthening mechanisms in metals

2020-2022 ARC – DP200100727 $361

Prof P Junk, Prof M Y Tan, Prof G Deacon Understanding and improving rare earth corrosion inhibitors

2020-2022 ARC – DP200100568 led by James Cook University

$420

Australian Research Council

Prof P Howlett, Prof M Forsyth, Dr R Kerr, Dr F Mizuno

Next-generation solid-state batteries to drive an automotive revolution

2019-2021 ARC and Toyota Motor Corporation – LP180100674

$316

Prof M Bouazza, Prof PJ Marriott, Dr W Gates, Prof A El-Zein, Prof R K Rowe

Designing the next generation of geosynthetic liner systems

2019-2021 ARC LP180101178, led by Monash University

$422

Prof D MacFarlane, A/Prof J Pringle, Dr M Kar, Mr S White

Phase change materials for wind and solar energy storage

2020-2023 ARC LP190100522, led by Monash University

$415

Australian Research Council Linkage Infrastructure Equipment and Facilities Program

Prof Tong Lin, Xin Wang, Prof Cuie Wen, Dr Nishar Hameed, A/Prof Olga Troynikov, A/Prof Lijing Wang, Prof Xungai Wang, Dr Rajiv Padhye

Manikin Flash Fire Evaluation System for Material Thermal Protection

2019-2020 ARC LIEF190100031 – led by RMIT University

Prof Yun Liu, Prof Kylie Catchpole, Prof Michelle Coote, Prof Hark Tan, Prof Xiu Song Zhao, Prof Douglas Robert MacFarlane, Prof Rose Amal, Dr Yun Hau Ng, Guohua Jia, Prof Yuan Chen, Prof Chuan Zhao, Dr Alexandr Simonov, Dr Zongyou Yin, Prof Ying (Ian) Chen

Multi-angle in-operando mapping of nanoscale electro/photo-catalytic reactions

2019-2020 ARC LIEF190100014 – led by Australian National University

Dr Luhua Li, Prof Kourosh Kalantar-zadeh, Prof Igor Aharonovich, A/Prof Wenlong Cheng, A/Prof Yuerui Lu, A/Prof Jacek Jasieniak, Prof Nicolas Voelcker, Prof Min Gu, Prof Mark Banaszak Holl, Prof Dan Li, Prof Tao Wu, Prof Matthew Phillips, A/Prof Brian Abbey, Prof Ann Roberts, Dr Qiaoliang Bao

Multi-functional 3D imaging system for on-working devices

2019-2020 ARC LIEF190100116 – led by Monash University

Australian Research Council Industrial Transformation Research Hubs

Prof V Sahajwalla, Prof D Giurco, Prof S Bhattacharya, Prof A O'Mullane, Prof A Tricoli, Dr N Florin, Prof P Perez, Dr F Pahlevani, Dr R Joshi, Dr T Boehme, Dr N Sharma, Dr S Maroufi, Prof H Wang, Prof M Forsyth, Dr A Malik, Dr R Kerr, Dr C Pozo-Gonzalo, Prof S Zhang, A/Prof P Sonar

ARC Research Hub for Microrecycling of Battery and Consumer Wastes

IH190100009 – led by the University of New South Wales

$3,357

Other Commonwealth Funding

National Health and Medical Research Council

Dr Emily Kerr, Prof Luke Henderson Point-of-care technologies for disease diagnosis

2019-2022 NHMRC Early Career Fellowship

$327

Medical Research Future Fund

Prof G Tachedjian, Dr C Bradshaw, Dr S Cook, A/Prof S Moulton, Dr D Bateson, Dr R Gorkin, Prof J Ravel, Dr G W Greene, Dr C K Fairley

Enhancing the Vaginal Environment and Microbiome

2019 Medical Research Future Fund (MRFF)

$895

Team Project title Years Industry Partner / Funding Body

Total Awarded ($AU,000)



28deakin.edu.au/ifm

Cotton Research & Development Corporation

Dr Maryam Naebe, Prof Xungai Wang Breathable cotton for compression fabrics phase 2: performance testing

2019-2020 CRDC $161

CSIRO

Prof Lingxue Kong, Dr Shuaifei Zhao Water production from CO2-capture 2019-2020 CSIRO Grant – Research – Commonwealth Scientific and Industrial Research Organisation

$100

Department of Industry, Innovation and Science

Prof Matthew Barnett, Prof Svetha Venkatesh Commercialisation of a unique, multidisciplinary approach to rapid alloy development.

2019-2020 DIIS – AusIndustry Accelerating Commercialisation grant

$250

A/Prof Daniel Fabijanic, Dr Santiago Corujeira Gallo, Prof Matthew Barnett

Improving the performance of high manganese steels used in rock crushing applications.

2019-2020 DIIS – AusIndustry Innovation Connections, H-E Parts International Crushing Solutions

$110

Dr Matthias Weiss, Dr Mariana Paulino Analysis of Material Behaviour in the Formflow Bending Process.

2019-2020 DIIS – AusIndustry Innovation Connections, Australian Engineering Solutions

$100

Dr Matthias Weiss, Dr Buddhika Abeyrathna, Dr Michael Pereira

Improving performance and quality of sound and fire barrier panels.

2019-2020 DIIS – AusIndustry Innovation Connections, Speedpanel (Vic) Pty Ltd

$111

Prof Russell Varley, Dr Jerry Gan, Dr Mandy De Souza

Next Generation Prepregs for Advanced Composite Materials Phase II.

2019-2020 DIIS, AusIndustry Innovation Connections, GMS Composites

$64

A/Prof Minoo Naebe, Dr Omid Zabihi Polymer composite materials for construction application

2019-2020 DIIS, AusIndustry Innovation Connections, DemTech

$80

Prof Bernard Rolfe, Dr Matthias Weiss, Prof Russell Varley, A/Prof Minoo Naebe, Prof Peter Hodgson, Prof Matthew Barnett, Dr Thomas Dorin, Dr Kazem Gabraie

Materials development and design for electrification and automation

2019 DIIS Automotive Engineering Graduate Program

$242

Defence Science & Technology Organisation (DSTO)

Dr Pavel Cizek, Dr Sitarama Kada, Dr Peter Lynch

Development of a Microstructural Damage Accumulation Model to Determine the Fatigue Life of Aerospace Materials – Part II

2019-2020 DSTO $100

Dr Ilana Timokhina, A/Prof Daniel Fabijanic Ti6AI4V powder production from swarf for 3D printing and advanced characterization of additively manufactured complex microstructures.

2019-2020 DSTO $60

Dr Ilana Timokhina Advanced microstructural characterisation and analysis of additively manufactured high temperature materials and laser-clad metallic alloys.

2019-2020 DSTO $90

Australian Academy of Technology & Engineering

Dr Jinfeng Wang, Dr Bin Tang, Prof Xungai Wang

Achieving a sustainable wool scouring process through converting scouring sludge to resources

2019-2020 AATSE Global Connections Fund Bridging Grant, Zhejiang YongJin Biotechnology Co Ltd

$76

Victorian Government

Sustainability Victoria

A/Prof Minoo Naebe, Dr Kamyar Shirvani Moghaddam, Dr Omid Zabihi, Dr Sobhan Fakhrhoseini

Catalyst assisted polyethylene (PE) recycling

2019-2022 Sustainability Victoria $195

Dr Md Mokhlesur Rahman, Prof Ying (Ian) Chen

Recycling silicon from photovoltaic panels for making advanced Lithium-ion batteries

2019-2022 Sustainability Victoria $150





29deakin.edu.au/ifm

Veski

Dr Emily Kerr, Prof Luke Henderson, A/Prof Mahiar Hamedi

Micro-total analysis systems for disease diagnosis

12/07/1905 VESKI Victoria Fellowship $18

Industry and Other Funding

Dr Julie Sharp SPF for stimulation of the immune system and immune cell programming.

2019-2020 Cytomatrix research grant $84

Prof Lingxue Kong, Dr Ludovic Dumee, Dr Fenghua She

Developing a PCR testing method for mock virus particles using MVM-MVP KIT from MOCKV solutions.

2019 CSL Behring (Australia) Pty Ltd

$56

Prof Xungai Wang, Dr Jinfeng Wang, Dr Bin Tang,

Natural fibre-reinforced biodegradable materials.

2019-2021 Fusion Biobased Materials Pty Ltd

$105

Dr Fenghua She, Dr Jane Zhang Characterization of Templated Fabrics 2019-2020 Gale Pacific Limited $4

A/Prof Alessandra Sutti APRI internship Martina di Venere 2019-2020 Haemograph Pty Ltd $20

A/Prof Alessandra Sutti, Dr Julie Sharp, Dr Surya Subianto

Advanced fibre for targeted delivery of bio-active molecules to treat chronic wounds.

2019-2020 Cytomatrix research grant $147

A/Prof Alessandra Sutti, Dr Surya Subianto

Dynamic thermomechanical analysis of textile materials.

2019 Xefco Pty Ltd $4

A/Prof Nolene Byrne Nanollose contract 2019-2020 Nanollose Limited $7

A/Prof Rimma Lapovok, Dr Ilana Timokhina

Upscaling ECAP-BP rig for industrial compaction of titanium swarf

2019-2020 Transform Metals Pty Ltd $35

Dr Luhua Li Research and development on the upscaling of boron nitride nanotube manufacturing facility.

2019-2020 BNNT Technology Limited $117

Prof Ying (Ian) Chen, Dr Lihua Li, Dr Baozhi Yu

Joint Venture Agreement on BNNT Applications

2019-2022 PPK Group Limited $5,800

Dr Wren Greene Method of Nanofabrication 2019-2020 Innovyz Advanced Materials & Manufacturing Pty Ltd

$10

Prof Mike Yongjun Tan, Mr Ivi Cicak

Pipeline coating testing and assessment 2019-2020 Industry projects with the National Facility for Pipeline Coating and Assessment

$270

Dr Matthias Weiss Development and experimental validation of a numerical model of the FormFlow bending process to analyse forming forces and material deformation.

2019-2020 Formflow Pty Ltd $5

Prof Frank Collins, Dr Will Gates

Viability assessment of Western Plains basalt as coarse aggregate in concrete.

2019 Cement, Concrete and Aggregates Australia

$24

Prof Russell Varley, Dr Claudia Creighton, Dr Srinivas Nunna, A/Prof Minoo Naebe, Prof Luke Henderson

Improving Compression Strength of Composites: Raw Materials and Better Pultrusion.

2019-2021 Vestas – Australian Wind Technology Pty Limited

$769

Dr Dylan Hegh, A/Prof Joselito Razal Researching the origin of creasing sheets and pillowcases after laundering and drying,

2019 Simba Global Pty Ltd $2

Dr Rainier Catubig, Dr Anthony Somers Crack propagation and erosion of metallic heat exchanger components

2019 InKorr Pty Ltd $6

A/Prof Minoo Naebe Carbon Fibre from Victorian Lignite 2019-2020 Brown Coal Innovation Australia limited

$197

A/Prof Daniel Fabijanic The development of a hot dip galvanising process for self-drilling building screws

2019 ITW Construction, Asia Pacific

$80

Dr H Beladi, A/Prof D Fabijanic, Prof M Barnett

Atomic scale analysis of heat treated cold rolled rods

2020 Infrabuild Construction Solutions Pty Ltd

$49

Dr Emily Kerr, Prof Luke Henderson

Lindau Nobel Laureate meeting 2020 Australian Academy of Science

$7





30deakin.edu.au/ifm

Case Foundation

Prof Luke Henderson, Dr Ben Allardyce, Dr Dan Eyckens, Dr Kathryn E Fairfull-Smith

Antibiotic Joint Implants: Modifying Metal Surface Chemistry to Prevent Infection in Joint Replacements

2020 CASS Research Grant $40

Dr Qiran Cai High thermal conductivity of atomically thin boron nitride and its thermal expansion

2019 CASS Travel Award $3

Cooperative Research Centres

A/Prof Nolene Byrne Multi-channel hydrostatic pressure test kit

2019 Future Fuels CRC Ltd $75

A/Prof Nolene Byrne Australian Pipelines & Gas Association 2019 Future Fuels CRC Ltd $72

Prof Mike Yongjun Tan, Prof Yong Xiang, Mr Bob Varela, Mrs Indivarie Ubhayaratne

Gap analysis of smart monitoring and data analytics for fuel infrastructural networks.

2019 Future Fuels CRC Ltd $78

A/Prof Nolene Byrne, A/Prof Tim Hilditch, Dr Mathew Joosten

Future proofing plastic pipes 2019-2023 Future Fuels CRC Ltd $754

Mr Bob Varela, Prof Mike Yongjun Tan Closed-loop CP control system for fuel networks.

2019-2020 Future Fuels CRC Ltd $192

A/Prof Tim Hilditch, Prof Mike Yongjun Tan, A/Prof Daniel Fabijianic, Dr Ross Marceau, Prof Bruce Hinton, Dr Guillaume Michal, Prof Cheng Lu

Assessing atom probe tomography for understanding hydrogen interactions with steel pipelines

2019-2022 Future Fuels CRC Ltd $307

Dr Weiwei Lei, Dr Zhiqiang Chen, Dr Christopher Hurren, Dr Dan Liu

Atmospheric Plasma Coating System. 2019-2022 Innovative Manfacturing CRC Limited

$1,010

A/Prof Santu Rana, Prof Patrick Howlett, Prof Maria Forsyth, Dr Robert Kerr, Prof Svetha Venkatesh

The CRC-P for Advanced Hybrid Batteries 2019-2022 CRC-Projects, with Calix $962

A/Prof Daniel Fabijanic, Dr Santiago Corujeira Gallo, Prof Matthew Barnett

Long life alloy components for efficient hydrometallurgical processing.

2019-2021 CRC-Projects, with Callidus Welding Solutions Pty Ltd

$870

International Funding

Prof Bernard Rolfe, Dr Yong Sun, Dr Matthias Weiss, Dr Buddhika Abeyrathna

Towards a semi industrial flexible forming facility for low volume production.

2019-2023 Baosteel Australia Joint Research & Development Centre (Uni of Qld)

$250

Dr Yong Sun Investigation of residual stresses and product of strength and elongation of roll formed and Chain-die formed AHSS products.

2019-2020 Baosteel Australia Joint Research & Development Centre (Uni of Qld)

$20

Prof Lingxue Kong Membrane distillation for water treatment

2019-2021 Sustech Environmental Inc $120

Dr Maryam Naebe Bio based sustainable and natural material for additive manufacturing.

2019-2022 Ford USA Grant – Research

(US$)150

Dr Maryam Naebe Formation and characterization of sustainable insulating material for automotive application.


(US$)15

Dr Sulley Li, A/Prof Minoo Naebe

Textile grade PAN precursor for development of low cost carbon fibre.


(US$)150

Prof Tiffany Walsh A predictive model for the dissolution rate of mineral wool fibres as a function of fibre and solution composition.

2019-2022 Rockwool International $169

Dr Thomas Dorin, Dr Steven Babaniaris

Investigation of the extrusion properties and microstructural characterisation of the 7136 alloy.

2019-2020 Universal Alloy Corpo-ration

$50

Dr Matthias Weiss, Dr Buddhika Abeyrathna

Understanding Roll Formability of 6 Novelis Aluminium Alloys.

2019-2020 Novelis Inc $43

Dr Jinfeng Wang, Dr Bin Tang Recovering grease from scouring wastewater (Stage III)

2019 New Zealand Woolscouring Limited

$16





31deakin.edu.au/ifm

International Funding

Dr Jinfeng Wang, Dr Bin Tang, Prof Xungai Wang

Sustainable flocculants for scouring sludge composting.

2019-2020 Zhejiang YongJin Biotechnology Co Ltd

$45

Prof Luke Henderson Using electrochemically initiated radical polymerization to develop novel sizings for carbon fibers in high temperature applications.

2018-2021 Air Force Office of Scientific Research United States of America

(US$)150

Prof Luke Henderson, Dr David Hayne

Enabling Ring Opening Metathesis Polymerization from the Carbon Fiber Surface

Using Norbornene Derived Polymers

2019-2020 The United States Army Research Office

(US$)150

Prof Maria Forsyth, Dr Cristina Pozo-Gonzalo, Prof Jenny Pringle, Prof Ulrich Schubert

European Training Network in Innovative Polymers for Next-Generation Electrochemical Energy Storage

2019-2023 European Commission- Marie Curie Actions Fellowships

$0

Mr James Randall, Prof Russell Varley, Prof Luke Henderson, Dr Claudia Creighton, Dr Srinivas Nunna, Ms Huma Khan

Development of tailored carbon fibres for multifunctional composites

2020-2022 Deakin contribution – The Australia-Germany Joint Research Co-operation Scheme Universities Australia and the German Academic Exchange Service (DAAD)

$24

Prof Joselito Razal Endeavour Executive Leader Joselito Razal to visit Cornell University, USA

2019-2020 DET Endeavour Executive Leadership Award

$17






Publications

Books1. Fang, J; Lin, T (ed.) (2019), Energy Harvesting Properties of

Electrospun Nanofiber, IOP ebooks (ISBN 9780750320030).2. Yang, X (2019), Handbook of Nanofibers, Springer

International Publishing.

Book chapter1. Cao, Y; Shao, H; Wang, H; Lin, T; Fang, J (2019) Triboelectric

effect and triboelectric energy generators, in Fang J, Lin T, Energy Harvesting Properties of Electrospun Nanofiber, Chapter 3, IOP ebooks.

2. Dumbre, J; Langan, T; Dorin, T; Birbilis, N (2019), Optimised composition and process design to develop sc-enhanced wrought al-si alloys, in Chesonis C, Light Metals 2019, The Minerals, Metals & Materials Series, PP. 1431-1438, Springer International Publishing.

3. Gore, P; Purushothaman, A; Naebe, M; Wang, X; Kandasubramanian, B (2019), Nanotechnology for oil-water separation, in Prasad R; Karchiyappan T, Advanced research in nanosciences for water technology, PP. 299-339, Springer.

4. Lang, C, Fang, J, Lin, T (2019) Acoustoelectric energy conversion of nanofibrous materials, in Fang J, Lin T, Energy Harvesting Properties of Electrospun Nanofiber Chapter 6, IOP ebooks.

5. Niu, H, Zhou, H, Wang, H (2019) Electrospinning: an advanced nanofiber production technology, in Fang J, Lin T, Energy Harvesting Properties of Electrospun Nanofiber, Chapter 1, IOP ebooks.

6. Periyasamy, A; Rwahwire, S; Zhao, Y (2019), Environmental friendly textile processing, in Torres Martinez L; Kharissova O; Kharisov B, Handbook of Ecomaterials, PP. 1521-1558, Springer.

7. Qin, S; Liu, D; Lei, W (2019), 2D nanomaterials for electrokinetic power generation, in ZAFEIRATOS S, 2d Nanomaterials for Energy Applications Graphene and Beyond, PP. 245-270, Elsevier.

8. Shao, H; Wang, H; Fang, J (2019), Piezoelectric energy conversion performance of electrospun nanofibers, in Fang J; Lin T, Energy Harvesting Properties of Electrospun Nanofibers, PP. 1-42, IOP Publishing.

9. Yan, G; Niu, H; Lin, T (2019), Needle-less electrospinning, in Ding, B; Wang X; Yu, J, Electrospinning: nanofabrication and applications, pp. 219-247, Elsevier Science BV.

10. Yang, X; Fane, A; Wang, R (2019), Membrane distillation: now and future, in Kucera J, Desalination : Water from water, PP. 399-427, Wiley.

Journal Articles1. Abdikheibari, S; Lei, W; Dumee, L; Barlow, A; Baskaran,

K (2019), Novel thin film nanocomposite membranes decorated with few-layered boron nitride nanosheets for simultaneously enhanced water flux and organic fouling resistance, Applied surface science, Vol. 488, PP. 565-577, Elsevier.

2. Abeyrathna, B; Zhang, P; Pereira, M; Wilkosz, D; Weiss, M (2019), Micro-roll forming of stainless steel bipolar plates for fuel cells, International journal of hydrogen energy, Vol. 44, NO. 7, PP. 3861-3875, Elsevier.

3. Abolhasani, M; Naebe, M; Shirvanimoghaddam, K; Fashandi, H; Khayyam, H; Joordens, M; Pipertzis, A;

Anwar, S; Berger, R; Floudas, G; Michels, J; Asadi, K (2019), Thermodynamic approach to tailor porosity in piezoelectric polymer fibers for application in nanogenerators, Nano energy, Vol. 62, PP. 594-600, Elsevier.

4. Adams, S; Doeven, E; Quayle, K; Kouzani, A (2019), MiniStat: development and evaluation of a mini-potentiostat for electrochemical measurements, IEEE access, Vol. 7, PP. 31903-31912, Institute of Electrical and Electronics Engineers.

5. Agarwal, A; Hundal, A; Chen, J; Bilic, A; Xiang, W; Bhosale, S; Li, J; Evans, R; Gupta, A (2019), Direct connection of an amine to oligothiophene to generate push-pull chromophores for organic photovoltaic applications, Dyes and pigments, Vol. 162, PP. 315-323, Elsevier.

6. Ahmad, R; Hodgson, P; Zhang, X; Whan, A; Negus, K (2019), In vivo person specific human body simulation for development and optimisation of surgical methods and materials, Computer methods in biomechanics and biomedical engineering: imaging and visualization, Vol. 7, NO. 3, PP. 317-335, Taylor & Francis.

7. Ahmadi, M; Zabihi, O; Li, Q; Fakhrhoseini, S; Naebe, M (2019), A hydrothermal-assisted ball milling approach for scalable production of high-quality functionalized MoS2 nanosheets for polymer nanocomposites, Nanomaterials, Vol. 9, NO. 10, PP. 1-21, MDPI.

8. Al Faruque, M; Remadevi, R; Wang, X; Naebe, M (2019), Preparation and characterisation of mechanically milled particles from waste alpaca fibres, Powder technology, Vol. 342, PP. 848-855, Elsevier.

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397. Zhao, S; Golestani, M; Penesyan, A; Deng, B; Zheng, C; Strezov, V (2019), Antibiotic enhanced dopamine polymerization for engineering antifouling and antimicrobial membranes, Chinese chemical letters, PP. 1-4, Elsevier.

398. Zhong, F; He, Y; Wang, P; Chen, C; Lin, Y; Wu, Y; Chen, J (2019), Self-assembled graphene oxide-graphene hybrids for enhancing the corrosion resistance of waterborne epoxy coating, Applied Surface Science, Vol. 488, PP. 801-812, Elsevier.

399. Zhong, F; He, Y; Wang, P; Chen, C; Xie, P; Li, H; Chen, J (2019), One-step hydrothermal synthesis of reduced graphene oxide/aspartic acid intercalated layered double hydroxide for enhancing barrier and self-healing properties of epoxy coating, Reactive and Functional Polymers, Vol. 145.

400. Zhong, F; Wang, P; He, Y; Chen, C; Li, H; Yu, H; Chen, J (2019), Preparation of stable and superior flux GO/LDH/PDA-based nanofiltration membranes through electrostatic self-assembly for dye purification, Polymers for Advanced Technologies, Vol. 30, NO. 7, PP. 1644-1655, Wiley.

401. Zhou, C; Cun Jun, L; Gates, W; Zhu, T; Wei Hua, Y (2019), Co-intercalation of organic cations/amide molecules into montmorillonite with tunable hydrophobicity and swellability, Applied clay science, Vol. 179, PP. 1-11, Elsevier.

402. Zhou, L; He, Y; Shi, H; Xiao, G; Wang, S; Li, Z; Chen, J (2019), One-pot route to synthesize HNTs@PVDF membrane for rapid and effective separation of emulsion-oil and dyes from waste water, Journal of Hazardous Materials, Vol. 380, Elsevier BV.

403. Zhou, S; Liu, F; Wang, J; Lin, H; Han, Q; Zhao, S; Tang, C (2019), Janus membrane with unparalleled forward osmosis performance, Environmental science and technology letters, Vol. 6, NO. 2, PP. 79-85, American Chemical Society.



404. Zhou, X; Guo, S; Cai, Q; Huang, S (2019), Ceria/cobalt borate hybrids as efficient electrocatalysts for water oxidation under neutral conditions, Nanoscale Advances, Vol. 1, NO. 9, PP. 3686-3692.

405. Zhou, Y; Fang, J; Wang, H; Zhou, H; Yan, G; Shao, H; Zhao, Y; Lin, T (2019), Motion sensors achieved from a conducting polymer-metal Schottky contact, RSC advances, Vol. 9, NO. 12, PP. 6576-6582, Royal Society of Chemistry.

406. Zhu, C; Yang, H; Wu, A; Zhang, D; Gao, L; Lin, T (2019), Modified alkaline electrolyte with 8-hydroxyquinoline and ZnO complex additives to improve Al-air battery, Journal of Power Sources, Vol. 432, PP. 55-64, Elsevier.

407. Zhu, H; MacFarlane, D; Pringle, J; Forsyth, M (2019), Organic ionic plastic crystals as solid-state electrolytes, Trends in Chemistry, Vol. 1, NO. 1, PP. 126-140, Elsevier.

408. Zhu, H; Vijayaraghavan, R; Macfarlane, D; Forsyth, M (2019), Self-assembled structure and dynamics of imidazolium-based protic salts in water solution, Physical Chemistry Chemical Physics, Vol. 21, NO. 5, PP. 2691-2696, Royal Society of Chemistry.

409. Zhu, L; Naebe, M (2019), The use of micro-computed tomography to determine the fabric cross-sectional area and stress, Journal of the Textile Institute, Vol. 110, NO. 10, PP. 1459-1467, Taylor & Francis.

410. Zhu, L; Wang, X; Blanchonette, I; Naebe, M (2019), Thermal comfort properties of bifacial fabrics, Textile research journal, Vol. 89, NO. 1, PP. 43-51, SAGE Publications.

411. Zou, Z; Liu, X; Ding, J; Chen, T; Wang, X (2019), Activated carbon powder derived from cashmere guard hair, Journal of industrial textiles, PP. 1-17, SAGE Publications.

Conference papers1. Abeyrathna, B; Rolfe, B; Weiss, M (2019), A first step

towards an in-line shape compensation for UHSS roll forming, International Deep Drawing Research Group. Conference (2019 : 38th Enschede, The Netherlands), PP. 1-9, IOP Publishing.

2. Al Faruque, M; Remadevi, R; Wang, X; Naebe, M (2019), Wet spun composite fibres with enhanced thermal and moisture properties by incorporating waste alpaca powder, World Textile. Conference (19th : 2019 : Ghent, Belgium), PP. 1-5.

3. Armstrong, N; Lynch, P; Kada, S; Cizek, P; Kimpton, J; Antoniou, R (2019), Bayesian analysis of in-situ high-resolution X-ray diffraction synchrotron experiments of Ti-6Al-4V specimens undergoing tensile loading, Conference (2019 : Phoenix, Arizona), PP. 1-10, American Society of Mechanical Engineers.

4. Babaniaris, S; Ramajayam, M; Jiang, L; Langan, T; Dorin, T (2019), Developing an optimized homogenization process for Sc and Zr containing Al-Mg-Si alloys, Light Metals. Symposium (2019 : San Antonio, Texas), PP. 1445-1453, Springer.

5. Batsouli, D; Dragatogiannis, D; Corujeira Gallo, S; Zhang, Z; Dong, H; Kotsikos, G; Charitidis, C (2019), Numerical and experimental study of single fiber push-out test: Influence of fiber/matrix interface mechanical properties, European Society for Composite Materials.

6. Chai, R; Lou, Y; Yoon, J (2019), Assessment of newly developed ductile fracture criteria for lightweight metals, Engineering Plasticity and its Applications. Symposium (14th : 2018 : Jeju Island, Korea), PP. 42-47, Trans Tech Publications.

7. Creighton, C; De Souza, M; Varley, R; Antony, J (2019), Development of a light-weight seat structure using a hybrid material approach, in Droder K; Vietor T, Faszination Hybrider Leichtbau. Conference (2018 : Wolfsburg, Germany), PP. 61-67, Springer Vieweg.

8. Creighton, C; Lynch, P; Nunna, S; Fox, B; de Jong, M; Mudie, S (2019), Micro-waxs study of structural heterogeneity in single pan-precursor and subsequent carbon fiber. International SAMPE Technical Conference (2019: Charlotte, NC, USA), in SAMPE Conference Proceeding Society for Advancement of Material and Process Engineering, North America.

9. Dorin, T; Ramajayam, M; Langan, T (2019), Impact of Scandium and Zirconium on extrudability, microstructure and hardness of a binary Al-Cu alloy, Aluminium Two Thousand and ICEB. World Congress (2017 : Verona, Italy), Elsevier.

10. Fehervari, A; Gallage, C; MacLeod, A; Oliari Garcez, E; Zhang, J; Antic, A; Gates, W; Collins, F (2019), Workability and Fresh Properties of a Low CO2 Footprint Concrete, Concrete 2019, PP. 41-45, Concrete Institute of Australia.

11. Gates, W; Gibbs, D; Amstberg, M (2019), Resilience of Australian polymer-modified powdered sodium bentonite geosynthetic clay liners to downslope bentonite erosion, in Zhan L; Chen Y; Bouazza A, Environmental Geotechnics. International Congress (8th : 2018 : Hangzhou, China), PP. 633-640, Springer.

12. Henderson, L; Arnold, C (2019), In situ polymerisation on the carbon fiber surface for enhanced interfacial adhesion, American Chemical Society. National Meeting & Exposition (257th : 2019 : Orlando, Fla.), American Chemical Society.

13. Henderson, L; Eyckens, D; Randall, J (2019), Using SuFEx chemsitry to modify carbon fiber interfaces, American Chemical Society. National Meeting & Exposition (257th : 2019 : Orlando, Fla.), American Chemical Society.

14. Joosten, M; Huang, H; Vidler, C; Varley, R (2019), 3D printed continuous fibre composites: validation of design and analysis methods, in Unknown, Composite Materials. International Conference (22nd : 2019 : Melbourne, Vic.), PP. 1-7, Engineers Australia.

15. Langan, T; Ramjayam, M; Sanders, P; Wood, T; Dorin, T (2019), Heat treatments for precipitation of scandium-containing dispersoids in an si-containing aluminum alloys, Light Metals. Conference (2019 : San Antonio, Texas), PP. 1463-1467, Springer.

16. Latino, M; Varela, F; Forsyth, M; Tan, Y (2019), Coating ageing and its impact on CP conduction, in Australasian Corrosion Association, Corrosion and Prevention. Australasian Conference (2019 : Melbourne, Vic.), PP. 1-9, Australasian Corrosion Association.

17. Lynch, P; Creighton, C; Fox, D; Santiago, PM; Hawley, A; Mudie, S (2019), The mechanical performance of carbon fibres – addressing the role of microstructure, International SAMPE Technical Conference (2019: Charlotte, NC, USA), in SAMPE Conference Proceeding Society for Advancement of Material and Process Engineering, North America.

18. MacLeod, A; Catubig, R (2019), Performance of lanthanum 4-hydroxycinnamate in a polyurethane coating in simulated seawater -exposed cement solution, in Corrosion and Prevention 2019: Annual Conference of the Australasian Corrosion Association, Crown Towers, Melbourne, Australia. 18/11/2019

19. MacLeod, A; Dupont, M; Fehervari, A; Gates, W; Collins, F (2019), Seebeck effect in carbon-nanotube-reinforced cement pastes, in Foster S; Gilbert RI; Mendis P; Al-Mahaidi R; Millar D, Federation internationale du beton. Congress (5th : 2018 : Melbourne, Vic.), PP. 1-8, Federation internationale du beton.

20. Mahawish, A; Bouazza, A; Gates, W (2019), Factors affecting the bio-cementing process of coarse sand. Proceedings of the Institution of Civil Engineers: ground improvement Vol. 172, No. 1, pp. 25-26.



21. Merenda, A; Kong, L; Zhu, B; Duke, M; Gray, S; Dumée, L (2019), Functional nanoporous titanium dioxide for separation applications: synthesis routes and properties to performance analysis, in Pannirselvam M; Shu L; Griffin G; Philip L; Natarajan A; Hussain S, Water Scarcity. Workshops (2016 : Melbourne, Vic.), PP. 151-186, Springer.

22. Nicholas, K; Modepalli, V; Watt, A; Hinds, L; Kumar, A; Lefevre, C; Sharp, J (2019), Guiding Development of the Neonate: Lessons from Mammalia, Nestle Nutrition Institute Workshop Series, Vol 90, PP. 203-215.

23. Nguyen, P; Tran, T; Gupta, S; Rana, S; Barnett, M; Venkatesh, S (2019), Incomplete conditional density estimation for fast materials discovery, in Berger-Wolf T; Chawla N, Society for Industrial and Applied Mathematics. Conference (2019 : Calgary, Alta.), PP. 549-557, Society for Industrial and Applied Mathematics.

24. Oliari Garcez, E; Kabir, M; Subhani, M; MacLeod, A; Fehervari, A; Hall, M; Moulton, P (2019), Development of high strength self-compacting fibre reinforced concrete for prefabricated concrete industry, Advances in Civil Engineering and Materials & Sustainable Bio-composite Materials and Structures. International Conference & World Symposium (1st : 2018 : Nanjing, China), EDP Sciences.

25. Shanbhag, V; Pereira, M; Voss, B; Ubhayaratne, I; Rolfe, B (2019), Developing smart multi-sensor monitoring for tool wear in stamping process, Deep Drawing Research Group. Annual Conference (38th : 2019 : Enschede, Netherlands) ), PP. 1-8, IOP Science.

26. Varley, R; Henderson, L; Reyes, L (2019), Multi-aromatic epoxy-amine thermosets with high performance properties, American Chemical Society. National Meeting and Exposition (257th : 2019 : Orlando, Fla.), PP. 1-1, American Chemical Society.

27. Vellanki, P; Rana, S; Gupta, S; Leal, D; Sutti, A; Height, M; Venkatesh, S (2019), Bayesian functional optimisation with shape prior, Artificial Intelligence. AAAI Conference (2019 : 33rd : Honolulu, Hawaii), PP. 1617-1624, AAAI.

28. Zhou, H; Niu, H; Wang, H; Lin, T (2019), Anti-oil-fouling, easily-cleaning, superhydrophilic-superoleophobic fabrics, Fiber Society. Spring Conference (2019 : Hong Kong, China), PP. 66-68, The Fiber Society.


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