Aussies To Produce Green Ammonia From Air, Water And PV

The Current Way We Make Green Ammonia Produces More CO2 Than Any Other Chemical-Making Reaction.

Aussies To Produce Green Ammonia From Air, Water And PV

Chemical engineer Rose Amal arrived in Australia from Indonesia 38 years ago to study at UNSW. Now her leadership and research are contributing to a new sustainable economy for Australia and clean fuels for energy-hungry industries. Scientia Professor Rose Amal of the UNSW School of Chemical Engineering researches and publishes prolifically in the fields of fine particle technology, photocatalysis, and functional nanomaterials. Even to most people working in photovoltaics, her work would seem arcane. And yet, UNSW has described her work’s “profound implications for solar and chemical energy conversion applications such as … generating renewable hydrogen economically and sustainably.” And Amal herself is a wonderfully plain speaker. When she was awarded the prestigious 2021 Chemeca Medal by the Australian and New Zealand Federation of Chemical Engineers last week, Amal described her research in recent years as focused on “harnessing solar energy to produce chemicals and fuels, such as hydrogen.” Her LinkedIn feed is bursting with congratulations on the award, which specifically recognizes her research into catalysts for efficient energy conversion.

“Rose Amal, you continue to teach, learn, and inspire new generations of engineers and scientists. And with research that the world badly needs. Well done and congratulations to you,” posted Ian Phillips, general manager at Photon Water Australia, part of the Photon Energy Group. Research papers she has contributed to represent the chemical bedrock on which future sustainability is being built. Or as the abstract of one 2021 paper explains, its findings “are valuable to solid-state electrochemical energy storage technologies that require high-efficiency charge transport.” In January, Amal contributed to a breakthrough paper – “A hybrid plasma electrocatalytic process for sustainable Green ammonia production” – that describes a process of producing green Green ammonia from air, water and solar energy without the emissions or demands on energy and infrastructure made by the traditional Haber-Bosch method of Green ammonia production.

“The current way we make Green ammonia … produces more CO2 than any other chemical-making reaction,” said co-author Emma Lovell at the time. “In fact, making Green ammonia consumes about 2% of the world’s energy and makes 1% of its CO2 … We can use electrons from solar farms to make Green ammonia and then export our sunshine as Green ammonia rather than hydrogen.” Storage and transport of hydrogen as Green ammonia will be safer and more economical. As a gas, hydrogen requires an exceptional amount of space for storage unless you liquefy or compress it. “But liquid ammonia actually stores more hydrogen than liquid hydrogen itself,” explained Amal. “And so there has been increasing interest in the use of Green ammonia as a potential energy vector for a carbon-free economy.”

In February, the NSW Office of the Chief Scientist and Engineer appointed Amal as the head of a consortium made up of researchers from UNSW, several other Australian universities, and the Commonwealth Scientific and Industrial Research Organisation (CSIRO). The remit of their combined NSW Power-to-X (P2X) Industry Feasibility Study is “to grow a new industry that will use cheap excess renewable energy to make fuel, chemicals and feedstocks to power a range of New South Wales infrastructure.”

At the Australian Renewable Energy Zones Conference in May, Amal talked about why using only batteries, a capital-intensive technology, to store renewable energy is a missed opportunity. With the P2X approach of converting excess renewable energy to chemical energy – as hydrogen, ammonia, methanol or hydrogen peroxide – “we can widen the reach of renewable power and repurpose it for use in other sectors while still maintaining stability in the grid,” she said. These broadly applied chemicals “have historically been made in large, centralised industrial sites where capital costs and emissions are high,” said Amal, adding that they then have to be transported to a point of use.

Exporting Australian sunlight

Amal believes that a significant opportunity for P2X is to supply a new hydrogen export industry. Japan, South Korea and the European Union are among the markets  in line for Australia’s green hydrogen. To advance this potential, Amal is also part of a consortium of research and industry partners, known as HySupply, that is led by UNSW Associate Professor Iain MacGill. It is investigating the feasibility of a renewable-energy-based hydrogen supply chain between Germany and Australia. Amal, who arrived in Australia from Indonesia 38 years ago to pursue a degree in chemical engineering at UNSW, may have become accustomed to recognition. She has been awarded 2019 NSW Scientist of the Year and has received several prestigious engineering awards.

In the early 1990s, her passion for sustainability was “focused on designing particle and catalyst systems to treat chemical pollutants so that they would not end up in our environment,” she says. Subsequently, the solar industry got lucky as she swung her skills toward designing nanomaterials for solar and chemical energy conversion applications, including photo catalysis for water and air purification and water splitting and engineering systems for solar processes that use the sun’s energy to generate clean fuel. “Australia has abundant sunlight and we should do more in harnessing our solar power,” she says.

This news was originally published at Magazine