Plasma Chemistry and Plasma Processing, Vol.32, No.4, 845-858, 2012
Effect of Low Temperature Air Plasma Treatment on Wetting and Flow Properties of Kaolinite Powders
It was found in this study that the air plasma treatment of particular kaolinite has led to the change of its wettability, which was reflected in the decreased values of water contact angles of wetting from 88.7A degrees for virgin kaolinite to 86.3A degrees for 30 min air plasma treated one. Plasma treated samples show higher average surface energies in the wide range of coverage regimes in comparison to the virgin samples as determined by inverse gas chromatography. Results of these measurements confirmed our assumption, that air plasma treatment activates surface energy of the crystal planes of the kaolinite as reflected in the broadened dispersive surface energy distribution after 10 min treatment time. However with prolonged 30 min treatment time the dispersive surface energy distribution profile was decreased. We assume, that the latter decrease reflects the distorsion of the crystal lattice of the kaolinite as confirmed by FTIR analysis as reflected in changes of Si-O-Si and Al2O-H characteristic absorption bands. Calculated dispersive surface free energy for 24 % surface coverage was increased from original 35 mJ/m(2) to 40.3 and 40.8 mJ/m(2) for 10 and 30 min treatment times. There were determined yield locus and flow function dependencies at different stress levels for virgin and different time plasma treated samples (flow index-ff (c) , effective angle of internal friction-phi (e) , unconfined yield strength-I integral (c) ). It was found that by plasma treatment the character of the flow was shifting from region of very cohesive (ff (c) = 2.39) to the cohesive (ff (c) = 3.19). For untreated samples effective angle of internal friction was decreased with increasing applied consolidation stress, while for plasma treated kaolinite it was increased.
Keywords:Kaolinite;China clay;Air plasma treatment;Contact angle;Inverse gas chromatography;Surface energy analysis;Powder rheology;Ring shear cell tester;Wetting;FTIR