掺杂样品显示出比原始样品更宽的能带间隙值,这表明ACF材料的较大Eg使其在电子和空穴传输方面更有效率,银掺杂铜铁氧体的能带间隙在可见光区域内增强了光吸收,表明掺杂样品可以有效地用作光催化剂。
因此,能带间隙能量取决于尺寸、形状和维度等因素,能带间隙,结晶紫作为一种有色污染物,苯甲酸作为无色废水,用于检测所制备催化剂的光催化能力,通过使用紫外可见光谱仪,来计算废水的降解百分比。
石墨烯与银、掺杂铜铁氧体合成的,金属氧化物半导体光催化剂,在净水方面表现出了显著的应用潜力,这种复合材料具有高效的吸附和催化性能。
因此,可以有效地去除水中的有害物质和污染物,从而,它被认为是一种高效净水的利器,可以提供清洁安全的水资源。
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