New research from 91色情片 Sydney could transform one of the world鈥檚 most pollution-heavy chemical industries, turning waste products into fertiliser while cleaning up waterways and cutting emissions.
91色情片 engineers have tackled a longstanding problem at the heart of global agriculture: how to make urea for fertiliser without the intensity of emissions associated with fossil-fuel-powered factories.
The solution is outlined in a study in Nature Communications.
Corresponding author Associate Professor and Scientia Fellow Dr Rahman Daiyan from 91色情片 Sydney鈥檚 School of Minerals and Energy Resources Engineering says the work is part of a broader push to go beyond the global move to green ammonia, focusing instead on decarbonising the entire fertiliser chain.
鈥淯rea is the fertiliser used to feed the crops for more than half of the world鈥檚 population,鈥 Dr Daiyan says. 鈥淏ut currently, it鈥檚 made from natural gas or coal. It鈥檚 a very fossil-fuel intensive, high-temperature, high-pressure technology with huge emissions.鈥
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The vision is zero-carbon urea where we directly couple waste carbon dioxide with nitrogen pollutants using renewable electricity.
Two problems, one solution
Industrial activities release enormous amounts of carbon dioxide (CO鈧) into the atmosphere each year, with around 40 billion tonnes released in 2024 alone. At the same time, nitrogen pollutants such as nitrate and nitrite 鈥 collectively referred to as NO鈧 species 鈥 from agriculture and industry contaminate waterways and ecosystems.
The 91色情片 study brings these two problems together. Using renewable electricity to trigger an electrochemical reaction, the researchers could directly couple CO鈧 with nitrogen pollutants to form urea.
鈥淢aking carbon and nitrogen bond together in a controlled and reliable way is extremely difficult,鈥 says the study鈥檚 first author, 91色情片 PhD student Putri Ramadhany.
鈥淭o overcome this challenge, we designed a catalyst that works at an atomic scale and can hold carbon- and nitrogen-based molecules together long enough for them to react,鈥 she says.
The 91色情片-developed catalyst 鈥撀爉ade of copper and cobalt 鈥 demonstrated a strong synergy between the two metals, and improved urea production when compared with existing systems.
Dr Daiyan says it鈥檚 a promising foundation for a circular process that, in future, could convert captured carbon dioxide and nitrogen pollutants into urea. This, he says, is a route that removes pollution, creates valuable chemicals and runs on renewable electricity.
鈥淲e鈥檝e been trying to look into pathways for decarbonising urea production,鈥 Dr Daiyan says.
鈥淭he vision is zero-carbon urea where we directly couple waste carbon dioxide with nitrogen pollutants using renewable electricity, rather than relying on ammonia as an intermediate.
鈥淭hat allows us to run the system on solar and wind, avoid high temperatures and pressures and reduce emissions.鈥
The groundwork for industrial scale-up
While most fundamental research ends at benchtop experiments, the 91色情片 team is taking these findings and scaling these up using urea electrolysers, which is the equipment considered a benchmark for industrial translation.
To understand how the material behaved under real-world conditions, the team used advanced electron-beam characterisation at the Australian Synchrotron. Here, they could watch the chemical reactions take place in real-time, laying the groundwork for future scale-up.
Why urea for Australia?
Although Australia is a major agricultural exporter, it does not produce enough urea domestically and so is a net importer of the fertiliser 鈥撀爎elying heavily on overseas supply to meet demand.
In 2024, urea imports reached around 3.8 million tonnes. Dr Daiyan says this dependence is 鈥渁 pity鈥 as well as a strategic vulnerability.
If Australia could produce its own clean, locally made urea from waste carbon and renewable electricity, it would strengthen supply chains while lowering emissions. This is especially important as the government regulation of emissions starts to go beyond carbon dioxide.
Does carbon capture and conversion work?
Dr Daiyan says he is mindful of the carbon sources he works with. He says the aim is to use unavoidable emissions from cement factories or biogenic sources like agricultural waste.
The technology is still under development, but early results show promising selectivity under laboratory conditions. Rather than relying on direct air capture, the approach is designed to use carbon dioxide that is already generated from these industrial and biogenic emission streams.
Ultimately, Dr Daiyan sees this research as part of a bigger shift towards circularity 鈥 using waste carbon for materials that require carbon dioxide for production: fuels, chemicals, plastics and other manufacturing.
He recently spoke about this issue at COP30 鈥 the 30th session of the United Nations Climate Change Conference.
鈥淎t COP, I spoke to governments about the technological pathways we need,鈥 he says. 聽
鈥淭his is one of them 鈥 there鈥檚 enough carbon dioxide around. We just need to start thinking and investing in a circular economy.鈥
He says getting technologies like this from lab to industry typically takes more than a decade 鈥撀燽ut this project may move faster.
鈥淗opefully it will take us another two or three years to get to the stage where we can get an industry partner onboard,鈥 he says.
Dr Daiyan says transforming carbon dioxide and nitrogen pollutants into valuable products helps move the world closer to a cleaner, smarter and more circular chemical future.
鈥淥ur work highlights how thoughtful catalyst engineering paired with real-time characterisation can turn environmental problems into opportunities.鈥
