Litcius/Paper detail

Flow behavior of cementitious-like suspension with nano-Fe3O4 particles under external magnetic field

Dengwu Jiao, Karel Lesage, Mert Yücel Yardımcı, Caijun Shi, Geert De Schutter

2021Materials and Structures21 citationsDOIOpen Access PDF

Abstract

Abstract The flow behavior of cementitious-like (limestone powder) suspension containing nano-Fe 3 O 4 particles at constant shear rate of 10 s −1 , characterized by the evolution of apparent viscosity over time, is investigated under various magnetic fields. Results show that the limestone powder suspension at flow-state exhibits remarkable magneto-rheological responses, reflected by a significant increase in the apparent viscosity after applying an external magnetic field. A higher field strength corresponds to a more rapid and pronounced response. The apparent viscosity experiences a sudden alteration with the stepwise change of the magnetic field due to the formation or disintegration of magnetic clusters. Linearly increasing magnetic field strength at low ranges (e.g. 0 T–0.3 T) shows less influences on the evolution of apparent viscosity, while at relatively high magnetic field, the apparent viscosity gradually increases with the magnetic field strength and the increase rate is comparable to that obtained under constant high magnetic field of 0.75 T. When the magnetic field is removed, the apparent viscosity exhibits a sharp reduction. If the magnetic field strength linearly decreases to zero, however, the apparent viscosity continuously increases until reaching a peak and then gradually decreases. This research shows in different ways how a desired apparent viscosity level of a cementitious-like suspension can be reached by means of an external magnetic field.

Topics & Concepts

Magnetic fieldViscosityMaterials scienceSuspension (topology)Field strengthRheologyApparent viscosityShear rateComposite materialMagnetic nanoparticlesCondensed matter physicsMagnetizationNuclear magnetic resonanceNanotechnologyNanoparticlePhysicsMathematicsPure mathematicsHomotopyQuantum mechanicsInnovations in Concrete and Construction MaterialsConcrete and Cement Materials ResearchCalcium Carbonate Crystallization and Inhibition