High performance inorganic fullerene cage WS2 enhanced cement.

• • Novel inorganic fullerene tungsten disulfide (IF-WS 2) CEM1 nanocomposite. • • Formation of CaWO 4 interface layer between IF-WS 2 and hydration products. • • 1 wt% addition of IF-WS 2 provides highest energy adsorption capability. • • 86% improvement in flexural strength of IF-WS 2 enhanced 3D printed specimens. An original cement based material enhanced with inorganic fullerene tungsten disulfide (IF-WS 2) nanoparticles has been engineered with superb shock absorbing properties. Physical properties were attributed to the IF-WS 2 nano-hollow multiple layered onion-like structure. The effect of IF-WS 2 concentration at 0.1 wt%, 1 wt% and 5 wt% on the hydration kinetics of ordinary Portland cement (CEM1), electrical impedance, thermal stability, rheology and strength development was thoroughly evaluated. X-ray photoelectron spectroscopy (XPS), transmission electron microscopy (TEM) and X-ray diffraction (XRD) studies confirmed the formation of the new phase, calcium tungstate (CaWO 4), at the nano-particle/cement matrix interface during early hydration. 1 wt% IF-WS 2 additions enhanced the impact energy of CEM1 by 89% compared to the control. An IF-WS 2 cementitious mixture was developed for 3D printing based on the 1% WS 2 -CEM composition. The mix exhibited excellent workability and buildability enabling the creation of a layer-by-layer printed component. Intimate interlayer adhesion minimized the presence of voids leading to a high flexural strength of 6.7 MPa, which equated to an over 86% improvement compared to plain CEM1 printed components. This study showcases IF-WS 2 nanoparticles as a new ground-breaking additive enabling the production of high-performance cementitious construction materials, for use under extreme environments demanding high strength and impact resistance. [ABSTRACT FROM AUTHOR]