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Purpose

Tunnels are means of transport in mountainous region which have continuous ingress of water. The incorporation of graphene nanoplatelets (GNPs) in shotcrete will refine the pore and limit the ingress of water as this study aims to enhance the performance, durability and sustainability of shotcrete used in lining of tunnels.

Design/methodology/approach

An experimental investigation was conducted wherein shotcrete mixes were prepared by adding various dosages of GNPs by weight of cement to the mixes varying from 0.25% to 1%. The mixes were tested for key properties including compressive strength, flexural strength, permeability, durability and microstructural characteristics. The performance of the GNP-enhanced mixes was then compared to that of conventional shotcrete.

Findings

The results showed significant improvements in the mechanical and durability properties of the shotcrete with the inclusion of GNPs. Notably, there was a substantial reduction in permeability, suggesting better resistance to moisture ingress and environmental degradation. Improved bonding and refined microstructure were also observed, indicating enhanced long-term performance.

Research limitations/implications

Further research is needed to evaluate long-term field performance, scalability and cost implications of GNP incorporation in large-scale shotcrete applications.

Practical implications

The improved properties of GNP-enhanced shotcrete can lead to extended service life and reduced maintenance in tunnel and underground projects, offering practical benefits in both construction efficiency and life cycle cost savings.

Social implications

The use of durable and sustainable materials like GNP-enhanced shotcrete supports environmentally responsible construction practices and contributes to the development of safer, longer-lasting infrastructure.

Originality/value

This research introduces the novel application of GNPs in shotcrete to overcome common limitations such as cracking, high permeability and poor tensile strength. The findings contribute to the development of advanced, nanoengineered shotcrete materials for more resilient and sustainable infrastructure in challenging underground environments.

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