Probing the interactions between collector molecules and hydrophobic graphite surfaces using chemical force microscopy

Collectors are widely used in flotation to improve the interfacial hydrophobicity of valuable minerals. Clarifying the mechanism of action is therefore a prerequisite for developing new collectors for flotation intensification. In this study, chemical force microscopy was applied to directly characterize the interaction forces between a mineral surface (hydrophobic graphite) and two collector molecules (undecane and polar undecanoic acid). An undecane/undecanoic acid self-assembled monolayer was formed on the Au-coated tip of an atomic force microscopy (AFM) cantilever through chemical deposition. Jump-in phenomena were observed between the collectors and the hydrophobic surface, indicating the existence of an attractive force, which conformed to the EDLVO theories. Various experiments indicated that the interactions between undecane and the hydrophobic surface were stronger than those involving undecanoic acid, indicating that hydrophobic forces dominated the interactions. Using molecular dynamics simulations, the adsorption energies of undecane and undecanoic acid on the graphite surface were determined to be - 17.1 +/- 0.3 and - 14.1 +/- 0.5 kcal/mol, respectively. The consistency between the force and the adsorption energy results demonstrated that AFM is a credible technique to investigate the interaction mechanism between a mineral and a collector at a molecular level, and so will provide critical guidance for future collector screening and design.

Automated summary

This study used chemical force microscopy to characterize the interaction forces between a mineral surface and two collector molecules, and demonstrated that AFM is a credible technique for investigating the interaction mechanism between a mineral and a collector at a molecular level, providing critical guidance for future collector screening and design.