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Revolutionising the way we manage liquid waste

  • Revolutionising the way we manage liquid waste
    The project, which is called REBOOT, is headed by Assistant Professor Patrick Biller from the Department of Engineering, Aarhus University. The project officially starts on 1 January 2020, and will be run at pilot scale at the department's Centre for Biorefining Technologies at Foulum, which is already home to one of the world's largest HTL reactors. Photo: AU Foto.

About the entity

Aarhus University
Established in 1928, Aarhus University has since developed into a major Danish university with a strong international reputation across the entire research spectrum.

An engineer from Aarhus University has received the prestigious ERC Starting Grant for the launch of a new research project, which can have far-reaching and ground-breaking significance for the environment throughout the world. The project promises to completely revolutionise the way we manage liquid waste today.

The DKK 11.2-million grant from the prestigious ERC Starting Grant under the EU Framework Programme for Research and Innovation (Horizon 2020) sets in motion a project promising to deliver far more sustainable liquid waste management to benefit the environment around the world.

The project is headed by chemical engineer and Assistant Professor at the Department of Engineering, Aarhus University, Patrick Biller, who will use state-of-the-art technology known as continuous hydrothermal liquefaction (HTL) to recover phosphorus and carbon from manure and sewage sludge (carbon in the form of so-called biocrude, which can be refined e.g. into aviation fuel).

The project is ground-breaking because it will allow for almost 100% recycling of valuable resources in liquid waste management. In addition to biocrude, the end product consists of nothing more than clean freshwater, hydrogen and CO2. 

"I'm very grateful to have been awarded this grant, which makes it possible to develop this exciting new technology that will enable us to recover valuable phosphorus from waste otherwise difficult to manage," says Assistant Professor Patrick Biller.


If the project is successful, it will have a positive effect on the environment across the world, as it will make mining for phosphorus redundant and will provide us with sustainably fuel, recovered directly from our wastewater. Photo: AU Foto.

Today, phosphorus is a valuable and scarce resource, which is ranked among the top 20 most critical raw materials by the EU. Europe does not have its own phosphorus reserves, and is therefore primarily imported from North Africa where it is retrieved from mines as phosphate rock.

Mining for as well as refining and transport of phosphate rock for fertiliser is associated with considerable greenhouse gas emissions (3.1 kg of CO2 per kg of phosphoric fertiliser), and it has been assessed that phosphorus resources are so scarce that they will only meet our demands for a further 50-100 years; and when they are depleted, it will have dire consequences for humanity.

Every year, Danish agriculture imports 50,000 tonnes of phosphorus, because it is absolutely necessary to apply phosphoric fertiliser to crops if you want to be able to maintain the yield that is normal for modern agriculture.

Denmark's approx. 13 million pigs also produce large amounts of phosphate rich organic manure, which is difficult to reuse as fertiliser without harming the environment.

To recycle the phosphorus, farmers apply manure to fields as fertiliser, and in many countries this leads to environmental problems such as contamination of the aquatic environment, groundwater and air. The problem is that manure can contain large amounts of antibiotics, which can cause problems with antibiotic resistance when the slurry is dispersed in the fields.

The same problem applies to sewage sludge. Here, e.g. residues from microplastic, oestrogens, pathogens and pharmaceutical products, including antibiotics, make it very difficult to directly recycle the sludge.

"Due to the relatively high temperatures and pressures in the HTL reactor, all environmentally hazardous substances are destroyed, so that the phosphorus we eventually recover is clean, safe and plant-available," says Patrick Biller.

The project, which is called REBOOT, and which is headed by Patrick Biller from the Department of Engineering, Aarhus University, officially starts on 1 January 2020, at which point Patrick Biller will set up a research group for the project. The project will be run at pilot scale at the department's Centre for Biorefining Technologies at Foulum, which is already home to one of the world's largest HTL reactors.

The aim is to create a single cohesive system that is fed with sewage sludge and manure at one end, and which supplies the valuable raw materials at the other end. Patrick Biller will make it possible to do so e.g. by developing new solutions and technologies within catalysis, water purification and filtration.

If the project is successful, it will have a huge and positive effect on the environment across the world, as it will make mining for phosphorus redundant and will provide us with sustainably fuel, recovered directly from our wastewater. At the same time, it will have great significance for the problems associated with lack of sewage treatment in many developing countries, such as the spread of disease and other adverse health effects. 

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