The flotation and surface interaction of rutile with nonyl hydroxamic acid were investigated in this work. The results show that the adsorption density and flotation recovery of rutile have similar tendency, especially the maximum recovery and adsorption occur at pH about 7.5. In terms of Fourier transform infrared(FTIR) spectroscopic analysis, chemical adsorption is identified on the surface of rutile, where a chelate of O,O-five-membered rings with Ti^4+ on the surface of rutile may form. Adsorption measurements, Zeta potential test, IR spectrum analyses, and solution chemistry calculations illustrate that the adsorption on the rutile surface involves both physical and chemical adsorption, while chemical adsorption is dominant.
Jun WangHong-Wei ChengHong-Bo ZhaoWen-Qing QinGuan-Zhou Qiu
The adsorption behavior and mechanism of Bi(Ⅲ) ions on the rutile-water interface were investigated through micro-flotation, Zeta potential measurement, adsorption amount measurement and X-ray photoelectron spectroscopy(XPS). According to the results of micro-flotation, Bi(Ⅲ) ions could largely improve the rutile flotation recovery(from 62% to 91%), and they could increase the activating sites and reduce the competitive adsorption between nonyl hydroxamic acid negative ions and OH-ions, which determined that Bi(Ⅲ) ions were capable of activating rutile flotation. The adsorption of Bi(Ⅲ) ions onto the rutile surface led to the shift of Zeta potential into the positive direction, which was good for the adsorption of nonyl hydroxamic acid anions. In addition, the results of XPS indicated that the chemical environment around Ti atom had not changed before and after the adsorption of Bi(Ⅲ) ions. Based on the adsorption mechanism of Bi(Ⅲ) ions, it was deduced that firstly Bi(Ⅲ) ions occupied the vacancies of the original Ca^2+, Mg^2+ and Fe^2+ ions on the rutile surface; secondly Bi(Ⅲ) ions covered on the rutile surface in the form of hydroxides.
