Traditional concrete, primarily employed for structural purposes, ensures the safety and
reliability of infrastructure due to its excellent mechanical and durability properties. However …

Carbon nanotube (CNT) has been increasingly used in concrete due to its good mechanical
properties and electrical conductivity. Scholars around the world have carried out in-depth …

Two-dimension graphene-based nanomaterials (GBNs), such as multi-layers graphene
(GNPs) and graphene oxide (GOs) have been extensively applied to enhance the …

Graphene and graphene-based nanosheets (GNS) possess extraordinary mechanical,
chemical, thermal and electrical properties, enabling attractive applications, ranging from …

Conductive carbon nanomaterials have been extensively developed for smart cementitious
composites to gain multifunctionalities (eg self-sensing, self-healing, self-heating, and …

Graphene reinforced cement composites have been continuously reported in the past years
to exhibit extraordinary mechanical properties, durability and multi-functionality owing to the …

Carbon nanotubes (CNT) as a functional filler can increase the electrical conductivity
property of concrete and thus provide intrinsic self-sensing properties with no need for …

Self-sensing concrete combines electrically conductive filler material and conventional
building material together, and is able to realise a sensing function that by measuring the …

Contemporary infrastructure requires structural elements with enhanced mechanical
strength and durability. Integrating nanomaterials into concrete is a promising solution to …

Carbon-based conductive fillers have recently been incorporated into a cement matrix to
develop an intrinsic self-sensing concrete for data monitoring without the need for …