Civil Engineering Departmental Seminar - Green Manufacturing for Circular Economy: from Waste to Value Added Products

Green Manufacturing for Circular Economy: from Waste to Value Added Products

Sustainable, emission-free, and eco-friendly methods for fabricating high-quality materials have garnered significant attention in recent years as industries move away from traditional linear synthesis processes reliant on finite virgin resources. Increasingly, a circular model is being adopted, where end-of-life products are strategically recycled and reused as feedstock, contributing to the reduction of waste and the efficient use of resources.

This presentation highlights two innovative technologies that align with sustainability and circular economy principles in critical industries: rare earth element (REE) recovery and steel production. The first part of the talk explores a three-stage process for the selective purification of rare earth oxides (REOs) from end-of-life nickel-metal hydride (Ni-MH) batteries. This process enables the high-yield fabrication of defect-rich Mn1-x-y(CexLay)O2-δ ultra-thin films, which are tunable in thickness and exhibit exceptional optoelectronic properties. These films demonstrate remarkable capacitance retention and energy density, positioning them as promising candidates for advanced energy storage devices. By recycling rare earth elements and integrating them into energy storage systems, this approach embodies a fundamental principle of the circular economy—extending material life cycles and reducing reliance on finite virgin resources.

The second part of the presentation addresses the steel industry, one of the largest energy consumers and carbon emitters in manufacturing. Traditionally reliant on coke, the industry is shifting toward more sustainable practices through the adoption of Polymer Injection Technology (PIT), developed at the SMaRT Centre at UNSW. PIT, which has been implemented by Electric Arc Furnace (EAF) steelmakers across Australia, Asia, and Europe, has led to substantial reductions in energy consumption, enhanced furnace efficiency, and decreased coke usage. Additionally, PIT helps divert millions of waste tyres from landfills, transforming waste into valuable feedstock for steel production. These technological advancements demonstrate the potential of circular economy solutions to reduce environmental impacts and enhance resource efficiency in heavy industries.