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研究报告

Optimal preparation conditions of sepiolite-supported nanoscale iron using response surface methodology

摘要：以直接耐晒黑为目标污染物,以FeSO₄浓度、KBH₄浓度和改性海泡石的投加量为影响因素,应用Box-Behnken响应曲面法进行了三因素三水平试验,优化了以改性海泡石为载体的纳米铁材料的制备方法.结果表明:在所选的试验范围内,FeSO₄浓度和KBH₄浓度的交互作用对纳米铁材料的制备有显著影响,对其去除直接耐晒黑性能的影响起到了关键性作用,且FeSO₄浓度的影响更为显著;而改性海泡石的投加量和KBH₄浓度的交互作用不显著.改性海泡石负载纳米铁的最佳制备条件为:0.13 mol·L^-1的FeSO₄溶液50 mL,0.18 mol·L^-1的KBH₄溶液50 mL,改性海泡石的投加量为2.86 g.在此条件下制得的纳米铁材料,其XRD谱图在2θ=44.7°处出现了Fe⁰的特征衍射吸收峰;对直接耐晒黑处理3 h后,直接耐晒黑的去除率可达98.9%,比仅采用改性海泡石的去除率提高了35.7%.

Abstract：In this study, preparation conditions of sepiolite-supported nanoscale iron were optimized by Box-Behnken response surface methodology. The FeSO₄ concentration, KBH₄ concentration, and modified sepiolite dosage were chosen as impact factors. The experiments were performed using direct fast black as target pollutant. The results showed that the interaction between FeSO₄ and KBH₄ concentration on the removal direct fast black by sepiolite-supported nanoscale iron had a significant effect, and FeSO₄ concentration was more significant within the selected test range. On the contrary, the interaction between modified sepiolite dosage and KBH₄ concentration was not significant. The optimum preparation conditions of sepiolite-supported nanoscale iron were 50 mL FeSO₄ with concentration of 0.13 mol·L^-1, 50 mL KBH₄ with concentration of 0.18 mol·L^-1, and the sepiolite dosage of 2.86 g. Under the optimum conditions, the removal percentage of direct fast black was 98.9% using sepiolite-supported nanscale iron at 3 h. The removal percentage increased by 35.7% compared with using the modified sepiolite alone. In addition, the sepiolite-supported nanoscale iron had the characteristic diffraction peak of Fe⁰ detected at 2θ=44.7° in the XRD patterns.

Key words：sepiolite nanoscale iron direct fast black response surface methodology