Titanium hydrolysate and iron-rich lixivium were obtained from the ilmenite by mechanical activation and hydrochloric acid leaching. By using H2O2 as a coordination agent, titanium was leached from the titanium-slag and a coordination lixivium was obtained. A nano-sized platelike peroxo-titania compound was prepared by heating the coordination lixivium. The peroxo-titania compound was washed and sintered, then a nano-sized platelike TiO2 (99.31%, mass fraction) was obtained. Li4Ti5O12 was synthesized by sintering the mixture of peroxo-titania compound and Li2CO3, the sample shows a good electrochemical performance as an anode material for the lithium-ion batteries. A selective precipitation method was used to synthesize FePO4-xH2O precursor from the iron-rich lixivium. The Ti-Al doped LiFePO4 was prepared using the FePO4·xH2O as the starting material. The as-prepared LiFePO4 exhibits a first discharge capacity of 151.3 and 140.1 (mA·h)/g, respectively, and shows no capacity fading after 100 cycles. Also, this method was used to synthesize the high-performance LiFePO4 from the ferrous sulfate waste slag produced by the titanium dioxide industry.%以钛铁矿为原料,经机械活化-盐酸浸出得到水解钛渣和富铁浸出液;用H2O2将水解钛渣中的Ti配位溶出,得到配位浸出液,并以其为反应物制备纳米级片状的过氧钛化合物;该过氧钛化合物经洗涤、煅烧制备得到纳米级片状的TiO2,其纯度高达99.31%(质量分数).将过氧钛化合物与Li2CO3混合,球磨后煅烧合成性能优良的锂离子电池负极材料Li4Ti5O12.以富铁浸出液为原料,经选择性沉淀制备含少量Al和Ti的FePO4·xH2O,并以其为前驱体制备了Al-Ti掺杂的LiFePO4.该LiFePO4在1C和2C倍率下的首次放电比容量分别达151.3和140.1(mA·h)/g,循环100次之后容量无衰减.该方法也可用于钛白粉副产品硫酸亚铁的回收利用,制备性能优异的LiFePO4.
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