A team of researchers from the Shibaura Institute of Technology in Japan has developed a pioneering construction material that transforms industrial waste into a high-performance, cement-free soil solidifier. This new material holds particular relevance for architects, civil engineers, landscape architects, and infrastructure developers seeking low-carbon, circular alternatives in soil stabilization and foundation systems.

Cement-Free Ground Stabilisation

Traditionally, Ordinary Portland Cement (OPC) has been the go-to material for stabilising soil in construction. However, its high carbon footprint—responsible for an estimated 7–8% of global CO₂ emissions—makes it unsustainable in the long run. Simultaneously, construction and demolition waste continues to grow, burdening landfill systems worldwide.

In response, researchers led by Professor Shinya Inazumi have developed a geopolymer-based alternative using two types of waste: Siding Cut Powder (SCP), a byproduct of construction processes, and Earth Silica (ES), derived from recycled glass. When activated together, these materials form a robust, environmentally responsible solidifier that exceeds the industry benchmark for compressive strength (160 kN/m²).

Performance and Environmental Safety

Thermal processing of the SCP at 110°C and 200°C was found to significantly enhance the reactivity of the material, allowing for reduced material usage without compromising performance. Notably, the formulation also overcame environmental concerns around arsenic leaching from recycled glass. The researchers successfully neutralised this issue by incorporating calcium hydroxide, which stabilises arsenic into non-leachable calcium arsenate compounds, ensuring compliance with environmental safety standards.

Applications Across Built Environments

This innovation is especially promising for urban development projects, such as roads, foundations, and bridgeworks, where weak or problematic soils often require treatment. It also offers a rapid, workable solution for disaster recovery efforts and rural infrastructure development, providing a low-carbon alternative to traditional fired bricks or concrete blocks.

With proven resistance to sulfate attack, chloride ingress, and freeze-thaw cycles, the solidifier is suitable for demanding environments, expanding its use across various climate zones. Its adoption could also help construction projects meet green building certification criteria and benefit from carbon credit incentives in regions with emissions-based policies.

A Circular Approach to Construction

By repurposing readily available waste streams, this geopolymer technology embodies the principles of the circular economy. It not only diverts construction and glass waste from landfills but also reduces reliance on carbon-intensive OPC, offering a practical pathway toward more sustainable building practices.

As urbanisation accelerates and infrastructure demands soar, innovations like this may redefine material sourcing and environmental responsibility in the built environment—supporting a transition to greener, circular construction systems.

Source: Shibaura Institute of Technology