Discovery Recovers Heavy Metals From Biosolid Waste
Author: Will Wright - RMIT University
Published: 2023/06/21 - Updated: 2025/04/07
Publication Details: Peer-Reviewed, Environmental Science
Category Topic: Food Security - Related Publications
Page Content: Synopsis - Introduction - Main - Insights, Updates
Synopsis: This article explores the potential of pyrolysis technology as a sustainable solution for managing agricultural and food waste while addressing environmental challenges. Pyrolysis, a thermochemical process, converts organic materials into valuable by-products such as biochar, bio-oil, and syngas, which can be used for energy production and soil improvement. The process is particularly relevant for enhancing food security in arid regions, reducing greenhouse gas emissions, and providing localized energy solutions. Its ability to handle diverse feedstocks and scale across different settings makes it appealing not only for agricultural applications but also for communities facing waste management issues. This information may be especially useful for seniors and individuals with disabilities who rely on equitable access to sustainable resources and clean environments - Disabled World (DW).
- Definition: Pyrolysis
Pyrolysis is one of the technologies available to convert biomass to an intermediate liquid product that can be refined to drop-in hydrocarbon biofuels, oxygenated fuel additives and petrochemical replacements. The pyrolysis (devolatilization) process is the thermal decomposition of materials at elevated temperatures, often in an inert atmosphere. Pyrolysis is most commonly used in the treatment of organic materials. In general, pyrolysis of organic substances produces volatile products and leaves char, a carbon-rich solid residue. Extreme pyrolysis, which leaves mostly carbon as the residue, is called carbonization. Bio-char produced can be used on farms as an excellent soil amender that can sequester carbon. Bio-char is highly absorbent and therefore increases the soil's ability to retain water, nutrients and agricultural chemicals, preventing water contamination and soil erosion.
Introduction
"Investigations Into the Closed-Loop Hydrometallurgical Process for Heavy Metals Removal and Recovery From Biosolids via Mild Acid Pre-Treatment" - Hydrometallurgy.
Engineers at the Royal Melbourne Institute of Technology (RMIT) in Melbourne, Victoria, Australia, have developed a cost-effective and environmentally friendly way to remove heavy metals, including copper and zinc, from biosolids.
Main Content
The team's work, led by RMIT University in collaboration with South East Water and Manipal University in India, advances other methods for heavy-metal removal by recycling the acidic liquid waste that is produced during the recovery phase, instead of throwing it away.
Lead senior researcher Professor Kalpit Shah from RMIT said the heavy metals found in biosolids - treated sewage sludge - can be valuable, and the recovery of metals such as copper and zinc can be achieved using the team's approach.
"Our innovation helps ensure the resulting biosolids do not leach heavy metals into the environment and retain the nutrients that can be used for land applications," said Shah, Deputy Director (Academic) of the ARC-funded Training Centre for the Transformation of Australia's Biosolids Resources in RMIT's School of Engineering.
"With further processing, the biosolids can be turned into high-grade biochar, which is a renewable energy resource and has a range of applications including as a fertiliser."
The research is published in the international journal Hydrometallurgy.
How Does the Innovation Work?
The overall metal-removal process occurs over three stages: extraction, purification and recovery.
Prior to the team's work, metal recovery from biosolids had not been fully explored among researchers beyond the first stage.
The first author of the journal article, RMIT PhD researcher Ibrahim Hakeem, said biosolids can contain several metals locked within organic matter, making purification and metal recovery challenging.
"We devised an approach where we were able to recover the metals one by one and did so with a closed-loop solution that causes least harm to the environment," said Hakeem, from RMIT's School of Engineering.
Co-author from Manipal University, Dr Abhishek Sharma, said this work was beneficial for improving the efficiency of the overall process during biosolids conversion to biochar via pyrolysis.
Shah said the work complemented the team's biochar-producing pyrolysis technology, which South East Water, Intelligent Water Networks (IWN) and Greater Western Water are trialling at the Melton Recycled Water Plant.
"Pyrolysis is a process that uses heat to break down organic materials into valuable products and occurs without oxygen to prevent the materials from burning. The team uses this process to remove pathogens and contaminants of emerging concern from biosolids."
Co-author and Deputy Director (Industry) of the ARC-funded Training Centre for the Transformation of Australia's Biosolids Resources, Dr Aravind Surapaneni, said water industries globally were considering alternative thermal conversion technologies such as pyrolysis to address concerns over contaminants including per- and poly-fluoroalkyl substances (PFAS).
The challenge is that reducing the organic matter through pyrolysis results in a higher concentration of heavy metals in the biochar, which the team's new technique helps resolve.
The application of biosolids to agricultural land in Australia is subject to guidelines and regulations that specify limits for heavy-metal concentrations, ensuring that biosolids can be safely used as fertiliser.
What Are the Next Steps?
The team aims to work with water authorities to use its heavy-metal removal technique prior to pyrolysis.
"The transition to a circular economy is important for the water industry," said South East Water's R&D Manager, Dr David Bergmann.
"We have previously seen our sludge as waste, but now through research like this we are able to see that it's possible to clean it up and convert it into potential materials with value and further applications."
Shah said the team's innovation could also be used for other waste streams such as storm water lagoon sludge and mine tailings.
''We are planning to work with South East Water to do a techno-economic analysis which will hopefully lead to pilot-trialling."
"We're also keen to work with companies who manage stormwater lagoons as well as mine tailings. The next step of engagement with them could be testing their samples in our lab followed by the pilot-trialling,'' he said.
Co-authors are Ibrahim Hakeem, Pobitra Halder, Shefali Aktar, Mojtaba Hedayati Marzbali, Abhishek Sharma, Aravind Surapaneni, Graeme Short, Jorge Paz-Ferreiro and Kalpit Shah.
Insights, Analysis, and Developments
Editorial Note: Pyrolysis represents a promising intersection of environmental stewardship and practical innovation. By transforming waste into renewable resources, it offers a pathway to mitigate climate change while supporting food and energy security. As global challenges like resource scarcity intensify, adopting such technologies could redefine sustainability practices across industries and communities - Disabled World (DW).Attribution/Source(s): This peer reviewed publication was selected for publishing by the editors of Disabled World (DW) due to its relevance to the disability community. Originally authored by Will Wright - RMIT University and published on 2023/06/21, this content may have been edited for style, clarity, or brevity.