Ghadeer Jalloul, Aya Hachem, Mohammad H. Hashem, Ahmad B. Albadarin, Mohammad N. Ahmad
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In order to maximize the visible light exposure of the membranes, 3D printed membrane holders with square and circular shapes were designed to immerse the membrane in Tetracycline solution. The results showed that immobilizing P25 catalysts on the fibers of the membranes limited their visible light absorption when the light source was assembled on the top of the aqueous reaction medium. This occurred due to the membrane's opacity limited light penetration, resulting in uneven irradiation throughout its depth. Based on this, a new photocatalytic reactor design was proposed with immersed light illumination source to reduce the distance between the membrane and the light source for improved activation of the P25 particles. 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引用次数: 0
摘要
在可见光下运行的异相光催化技术被认为是去除水流中药物的一种高效、环保的方法。然而,纳米级催化剂颗粒的回收限制了该技术的小规模应用。在本研究中,我们制备了掺杂铁的 P25 TiO2 光催化剂,并将其固定在 PVDF-HFP 电纺丝膜上,用于在可见光下光催化降解四环素类抗生素。为确保纳米颗粒在纤维上的均匀分布,改变了电纺电压和 TiO2 的重量百分比,并采用两种制备方法将催化剂分散在聚合物溶液中。为了最大限度地提高膜的可见光曝光率,设计了方形和圆形的 3D 打印膜支架,将膜浸入四环素溶液中。结果表明,当光源装配在水性反应介质的顶部时,将 P25 催化剂固定在膜的纤维上会限制其对可见光的吸收。这是因为膜的不透明性限制了光的穿透,导致整个膜深度的照射不均匀。在此基础上,我们提出了一种新的光催化反应器设计,采用浸入式光源,以减少膜与光源之间的距离,从而提高 P25 颗粒的活化效果。在该设计中,还包括一个 3D 打印的垂直膜支架,以容纳更大的膜表面积,从而最大限度地减少大型工业应用所需的空间面积。
Fe-doped TiO2/PVDF-HFP electrospun membranes for tetracycline photocatalytic degradation under visible light
Heterogeneous photocatalysis operated under visible light is considered an efficient and ecofriendly method to remove pharmaceuticals from water streams. However, the recovery of the nano-sized catalyst particles limits this technology to small-scale applications. In this study, we prepared Fe-doped P25 TiO2 photocatalysts and immobilized them over PVDF-HFP electrospun membranes for the photocatalytic degradation of Tetracycline antibiotic under visible light. To ensure uniform distribution of the nanoparticles on the fibers, the electrospinning voltage and the weight percentage of TiO2 were varied, and two preparation methods were applied to disperse the catalyst in the polymeric solution. In order to maximize the visible light exposure of the membranes, 3D printed membrane holders with square and circular shapes were designed to immerse the membrane in Tetracycline solution. The results showed that immobilizing P25 catalysts on the fibers of the membranes limited their visible light absorption when the light source was assembled on the top of the aqueous reaction medium. This occurred due to the membrane's opacity limited light penetration, resulting in uneven irradiation throughout its depth. Based on this, a new photocatalytic reactor design was proposed with immersed light illumination source to reduce the distance between the membrane and the light source for improved activation of the P25 particles. In this design, a 3D-printed vertical membrane holder was also included to accommodate a larger membrane surface area and therefore minimize the required spatial area for large industrial applications.
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