The know-how for our decarbonisation lies with universities
Australia has been聽聽the global shift towards decarbonisation and lower emissions. Now, ready or not, the world is on the verge of a climate action crescendo. Australia can choose what to do next: act meaningfully and with determination; dither and have its hand forced; or, at worst, face punishing measures such as聽.
Despite our lumbering start, we are in a fortunate position. We do not need to start from scratch to green our economy and participate wholly in the decarbonisation revolution. While Australia debates 鈥渨here to from here鈥 as world leaders come together for聽聽in Glasgow, university researchers have long been heads down developing the very research, talent and technology we鈥檒l need for this transformation.
With the right mix of industry and government support, these university-developed resources will allow us to pivot to a decarbonised economy. Australia can emerge as a green export and research and development leader.
Professor Rasmussen is Deputy Dean and Associate Dean Research for the Faculty of Engineering.
Across engineering and science, we鈥檙e witnessing a research and technology explosion. The once unimaginable is being made possible. We are seeing advances in many fields, including:
renewable and low-emission technologies
energy generation, utilisation and storage
electrification and network hybridisation
power fuels, including hydrogen.
With our abundant natural and mineral resources and agricultural industry, these are all areas in which Australia can and should lead to become a research and development exporter. Aside from helping to transition our economy and lower emissions, this would attract further overseas talent and investment.
Australia has an untapped opportunity to switch from being an exporter of carbon fuels to an exporter of green fuels. We can do this by converting solar and wind energy to stored energy like hydrogen. For domestic consumption, there is a wider range of energy-storage options including batteries and Snowy 2.0.
Federal support for developing a green fuel export industry is growing slowly. However, industry and financial consortia have been investing rapidly in green technologies and plants.
Scale of challenge demands collaboration
Tackling climate change requires a collective approach. That鈥檚 because it affects every sector and part of society.
Associate Professor Thornber is an expert in computational fluid dynamics.
Universities were once considered somewhat siloed. Now they are working more closely with other institutions. Formerly disparate areas of expertise are being connected to develop research and technology to tackle and adapt to climate change.
Examples of collaboration range from historians and engineers working together to better understand how climate change led to the demise of聽聽through to using聽聽to better understand the impacts of the resource sector on the environment.
Increased collaboration between disciplines and institutes makes universities an attractive resource and 鈥渙ne-stop shop鈥 for companies looking to decarbonise or expand their offerings to compete in the green economy.
Snowy Mountains Hydro, while one of the most ambitious feats of engineering ever achieved, should not remain our nation鈥檚 industrial magnum opus.
Campuses too are being transformed into high-impact, industrial research hubs. They are gearing up for greater industry collaboration, testing and rapid prototyping.
These campus facilities include state-of-the-art infrastructure, ranging from nano technology and foundries to advanced manufacturing and microanalysis. They are helping to develop scalable and translatable research for both large existing companies and start-ups.
Research is already paying off
Universities are also increasingly commercialising their research and technology. In the process, they are developing companies with the potential to rewrite Australia鈥檚 climate change fate.
Agerris/Australian Centre for Field Robotics
One such company is agri-robotics start-up聽. It鈥檚 commercialising technology developed over the past 15 years from the University of Sydney鈥檚聽Australian Centre for Field Robotics, a source of聽several successful start-ups. Agerris鈥檚 robotics solutions to optimise farming have the potential to control emissions in agriculture and related areas including forestation and oceanography.
Another example is zinc-bromide battery developer聽Gelion. This spin-off from the University of Sydney聽Nano Institute聽is disrupting the solar energy industry with its safe, cost-effective products.
Gelion鈥檚 zinc-bromine battery is an example of how R&D can pave the way for manufacturing jobs to be created in the transition to a low-emissions economy.
Snowy Mountains Hydro, while one of the most ambitious feats of engineering ever achieved, should not remain our nation鈥檚 industrial magnum opus. It鈥檚 vital Australia embarks on an ambitious plan to lower emissions and decarbonise our economy. If we want the next big thing, we can bet universities are already developing the thinking and technology behind it.
All academics know that often the best students are the ones who work diligently and consistently over a long period. Others may wait until the last minute, with some bright, creative minds somehow always pulling through with distinction.
We are now at the 11th hour. Let鈥檚 hope Australia is that precocious student who can pull it all off in the nick of time.
This article was first published on聽 and was聽written by Professor Kim Rasmussen and Associate Professor Ben Thornber.听
Kim Rasmussen