Friday, January 12, 2024

Improving soil health with aeration curing for sludge management

Researchers demonstrate the potential of aeration curing for recycling sludge and immobilizing carbon dioxide in a cost-effective way.

Peer-Reviewed Publication

SHIBAURA INSTITUTE OF TECHNOLOGY

Aeration curing for efficient construction-generated sludge management. — IMAGE:
INFOGRAPHIC SHOWING HOW AERATION CURING HELPS NEUTRALIZE THE ALKALINE NATURE OF SOIL THROUGH CARBON DIOXIDE IMMOBILIZATION.
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CREDIT: SHINYA INAZUMI FROM SIT, JAPAN

The construction industry is recognized for its high resource consumption and large waste generation. Among the waste products generated are construction-generated sludge (CGS) and construction-generated surplus soil (CGSS). These can be used for various applications such as backfilling, the creation of environmentally friendly building materials like bricks, and soil stabilization. However, these materials are highly alkaline, and this poses a risk of soil and water contamination, which adversely impacts plant and animal life. Furthermore, the large volume of CGS and CGSS generated, along with its unlawful dumping, pose further challenges. Therefore, newer solutions are required for their management and recycling.

In a recent study led by Professor Shinya Inazumi from the College of Engineering at Shibaura Institute of Technology in Japan, a team of researchers has now addressed this issue by presenting a new, cost-effective strategy for the management of CGS. They have proposed the use of “aeration curing,” a technique that converts carbon dioxide to carbonate, as a solution. Their work was made available online on 23 November 2023 and published in Case Studies in Construction Materials on 01 July 2024.

Prof. Inazumi explains: “The initiation of the study on aeration curing was driven by the growing need to align construction practices with the sustainable development goals (SDGs). There is an urgent need for innovative solutions to effectively manage waste and reduce carbon footprints of the construction industry.”

The process of aeration curing involves carbon dioxide reacting with alkaline calcium hydroxide in the CGS to form less alkaline calcium carbonate. Notably, this neutralization method reduces the need for additional neutralizers, like sulfuric acid, typically required in more conventional treatment methods. Furthermore, traditional management practices are fighting rising costs of transportation, processing, and disposal.

For this study, aeration curing of CGS samples was conducted under various conditions. This involved manipulating factors, such as the speed of agitation, performing aeration curing within a drying oven, altering the surface area of the aerated region, and introducing a neutralizer to the samples. The findings revealed that the reduction in pH (a measure of alkalinity) was more pronounced at higher agitation speeds, during curing in a drying oven, and with a larger aerated surface area. Additionally, the aeration curing process required less neutralizer. These results highlight the potential of aeration curing as a sustainable construction practice for CGS management and carbon sequestration.

There are far-reaching implications of these findings, spanning various domains. Aside from waste management in the construction industry, the ability of the proposed method to neutralize soil can prove useful in land reclamation and remediation by preparing acidic or contaminated land for construction or agricultural use. Subsequently, this will help increase soil yields by improving overall soil health. Furthermore, this approach can be incorporated into academic curriculum and research projects that focus on environmental science and engineering, helping institutes explore sustainable waste management practices.

In the long term and from a big picture perspective, Prof. Inazumi speculates: “By aligning with the SDGs, aeration curing provides a practical tool for policymakers to promote sustainable practices in waste management and carbon sequestration. This, in turn, can influence regulations and guidelines related to construction and environmental protection. However, further refinement of the theoretical model is needed to accurately reflect real-world neutralization reactions.”

In summary, aeration curing, which can serve the dual purpose of soil neutralization and carbon sequestration, holds significant promise for influencing various disciplines and marks a crucial advancement in sustainable and environmentally responsible construction practices.

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Reference

Title of original paper: Aeration curing for recycling construction-generated sludge and its effect of immobilizing carbon dioxide

Journal: Case Studies in Construction Materials

DOI: https://doi.org/10.1016/j.cscm.2023.e02704

About Shibaura Institute of Technology (SIT), Japan

Shibaura Institute of Technology (SIT) is a private university with campuses in Tokyo and Saitama. Since the establishment of its predecessor, Tokyo Higher School of Industry and Commerce, in 1927, it has maintained “learning through practice” as its philosophy in the education of engineers. SIT was the only private science and engineering university selected for the Top Global University Project sponsored by the Ministry of Education, Culture, Sports, Science and Technology and will receive support from the ministry for 10 years starting from the 2014 academic year. Its motto, “Nurturing engineers who learn from society and contribute to society,” reflects its mission of fostering scientists and engineers who can contribute to the sustainable growth of the world by exposing their over 8,000 students to culturally diverse environments, where they learn to cope, collaborate, and relate with fellow students from around the world.

Website: https://www.shibaura-it.ac.jp/en/

About Professor Shinya Inazumi from SIT, Japan

Professor Shinya Inazumi is a faculty member at The College of Engineering at Shibaura Institute of Technology, Tokyo, Japan. He earned his Ph.D. from Kyoto University and has an extensive academic record with over 105 publications and 350 citations. He specializes in civil, geotechnical, and environmental engineering and has earned several prestigious awards, including the “ICE Publishing Awards 2020 (Environmental Geotechnics Prize)” from the Institution of Civil Engineers, the “International Research Award” from the International Society for Scientific Network Awards, and the “MEXT Young Scientists’ Prize” from the Ministry of Education, Culture, Sports, Science and Technology in 2015.

JOURNAL

Case Studies in Construction Materials

DOI

10.1016/j.cscm.2023.e02704

METHOD OF RESEARCH

Experimental study

SUBJECT OF RESEARCH

Not applicable

ARTICLE TITLE

Aeration curing for recycling construction-generated sludge and its effect of immobilizing carbon dioxide

£2.6 million center to train mineral resources experts for a new generation

Training and Research Group for Energy Transition Mineral Resources (TARGET) to be led by University of Leicester with universities, research organisations and industrial partners from across the UK

Business Announcement

UNIVERSITY OF LEICESTER

Copper mine in Arizona — IMAGE:
COPPER MINE IN ARIZONA
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CREDIT: SOURCE: UNIVERSITY OF LEICESTER

A new generation of mineral resource experts to enable the United Kingdom’s transition to sustainable energy are to be trained by a consortium representing academia and industry, led by the University of Leicester.

The Natural Environment Research Council (NERC), part of UK Research and Innovation, have announced £2.6 million to support a multi-institution centre for doctoral training, the Training and Research Group for Energy Transition Mineral Resources (TARGET), to address the skills and research needs for the UK.

It is one of four new Natural Environment Research Council-funded centres that will teach the next generation of PhD students who will go on to build careers in research, business and public service.

Each year, over 3 billion tonnes of metals are produced from mineral resources. Mineral resources underpin society – without them we would have no infrastructure, no industry and no technology.

The UK’s transition to renewable energy generation and use – through wind turbines, solar panels and electric vehicles for example – is increasing the demand for mineral resources. Some of them are considered ‘critical’ – economically important but with challenged supply chains that are vulnerable to disruption. Growing expertise in critical mineral resources will help to develop secure and sustainable supply.

The TARGET centre is a UK wide group of universities, research organisations and industrial partners, led by the University of Leicester’s Centre for Sustainable Resource Extraction that will provide doctoral-level training in the full lifecycle of minerals from sector leaders. TARGET is recruiting its first cohort of researchers to start in October 2024, with further information available at https://target.le.ac.uk/

TARGET’s leader Dr Dan Smith, from the University of Leicester School of Geography, Geology and the Environment, said: “TARGET is a really exciting opportunity for us to train a next generation of researchers with the skills they need to tackle some of the biggest challenges in mineral resources: how do they form? How can we find the raw materials we need? How can we process and extract them efficiently, and how can we be more sustainable whilst doing so?

“It’s not just about getting more resources either. We know we need more careful stewardship of the resources we do have – considering circular economy models, better waste management, and more efficient use of mineral products.”

The TARGET Centre will combine PhD research projects with a multidisciplinary training programme that will provide skills in mineral exploration, processing, finance, policy and sustainability at all stages of a mineral’s use – from a rock in the ground to the end of a product’s useful life. TARGET’s training will be led by a mix of academic researchers and industry practitioners, and the parentship of the centre includes some of the most important global companies in mining, mineral analysis, environmental standards, and finance.

TARGET will operate alongside other UKRI programmes, including the £15 million CLIMATES programme being delivered by Innovate UK, boosting rare earth circularity, to provide opportunities for UK industry and research to enhance the responsible supply of minerals.

Science, Research and Innovation Minister, Andrew Griffith, said: “Backing our brightest students to tackle issues as vital as flooding and protecting our water quality is an investment in protecting the landscape of the UK, while defending our planet and the resources we need to deliver us all healthier and more prosperous lives.

“With more than £10m in funding over the coming years it will also help to skill-up students in high-value research, which will grow the UK economy and ensure we fulfil the potential of the talent spread throughout our country.”

Professor Peter Liss, Interim Executive Chair of NERC, said: “This investment by NERC will equip the next generation of environmental science researchers with the technical and professional skills to tackle some of the most significant challenges facing the UK and globally.

“The new centres for doctoral training will focus on the key themes of flood management, freshwater quality, sustainable mineral resources and wetland conservation.”

TARGET is recruiting its first cohort of researchers to start in October 2024, for more information or to apply visit: https://target.le.ac.uk/
TARGET partners are University of Leicester, Cardiff University, University of Exeter, Natural History Museum, Imperial College, the British Geological Survey, the Geological Survey of Northern Ireland, University of Liverpool, University of Leeds, Brighton University, St Andrews University, University College London, University of Aberdeen, the Scottish Universities Environmental Research Centre, University of Southampton and University of Edinburgh.

Truck working at a mine

Drill rig in South Pacific.

CREDIT

Source: University of Leicester

Innovating Wastewater Treatment: A Leap from Experience to Intelligence

Peer-Reviewed Publication

CHINESE SOCIETY FOR ENVIRONMENTAL SCIENCES

Graphical abstract — IMAGE:
GRAPHICAL ABSTRACT
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CREDIT: ENVIRONMENTAL SCIENCE AND ECOTECHNOLOGY

In a recent study published online 18 December 2023 in the journal Environmental Science and Ecotechnology, scientists from Peking University introduced a groundbreaking Global WWTP Microbiome-based Integrative Information Platform to address the escalating complexities of pollutants and inadequacies in traditional WWTPs. This platform, inspired by the advancements in artificial intelligence (AI), is poised to revolutionize the field of environmental engineering and microbiome research.

The innovative platform harnesses extensive microbiome and engineering data from WWTPs around the world. By utilizing advanced AI-driven tools, it analyzes the data to identify optimal microbiomes, upgrade facilities, and effectively respond to pollution accidents. This AI-driven platform strives for a stronger, faster, and globally integrated wastewater treatment solution, thereby enhancing WWTPs' indispensable role in pollution control and environmental sustainability.

Highlights

A “Global WWTP Microbiome-based Integrative Information Platform” is proposed.
The Platform employs AI-driven modeling and analyzing for WWTP-relevant parties.
The Platform aims to enhance the biodegradation efficiency of pollutants on Earth.
The Platform will be of significance for our human society and natural environment.

"The Global WWTP Microbiome-based Integrative Information Platform is not just a technological advancement; it's a paradigm shift in how we cope with environmental challenges," stated Donghui Wen, a leading figure in environmental engineering. "By harnessing the power of AI and global data, we're moving from mere experience-based methods to an era of informed intelligence."

The implications of this platform are vast. It is expected to significantly enhance the performance of WWTPs in pollution control, contributing to a more harmonious and healthy future for human society and the natural environment. It supports multidisciplinary research, documents microbial evolution, advances wastewater-based epidemiology, and enhances global resource sharing.

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References

DOI

10.1016/j.ese.2023.100370

Original Source URL

https://doi.org/10.1016/j.ese.2023.100370

Funding information

The National Natural Science Foundation of China (51938001, 52170185, 42007291, 52070111)； The China Postdoctoral Science Foundation (2022M721815).

About Environmental Science and Ecotechnology

Environmental Science and Ecotechnology (ISSN 2666-4984) is an international, peer-reviewed, and open-access journal published by Elsevier. The journal publishes significant views and research across the full spectrum of ecology and environmental sciences, such as climate change, sustainability, biodiversity conservation, environment & health, green catalysis/processing for pollution control, and AI-driven environmental engineering. The latest impact factor of ESE is 12.6, according to the Journal Citation ReportTM 2022.