可见光协同氧掺杂石墨相氮化碳活化亚硫酸盐降解水中双酚A

内分泌干扰物是一种干扰动物内分泌系统、影响动物生殖发育的环境激素。典型内分泌干扰物双酚A(BPA)被界定为新兴污染物,会对环境和人体健康产生不利影响。采用简单热合成法制备了无金属的氧掺杂石墨相氮化碳(O-C_(3)N_(4))材料,使用高分辨透射电镜(HRTEM)对该催化剂的微观形貌进行了表征,研究了O-C_(3)N_(4)协同可见光活化亚硫酸盐石墨相氮化碳[即O-C_(3)N_(4)/S(Ⅳ)/Vis]体系降解BPA的动力学特征、环境因素影响和体系中活性氧物种(ROS)对BPA降解的贡献;考察了无机阴离子(Cl^(-)、HCO^(-)_(3)、SO_(4)^(2-)、NO^(-)_(3))和天然有机物对BPA降解效果的影响。结果表明:掺杂O原子后的石墨相氮化碳材料更加蓬松、多孔,可以为反应提供更多的活性位点;O-C_(3)N_(4)投加量为0.2 g/L、S(Ⅳ)投加量为0.3 mmol/L时光催化反应90 min对0.05 mmol/L BPA的去除率可达83.9%,是g-C_(3)N_(4)/S(Ⅳ)/Vis体系的4.23倍,是O-C_(3)N_(4)/S(Ⅳ)体系的4.82倍;在一定范围内,BPA的去除效果随着O-C_(3)N_(4)和S(Ⅳ)投加量的增加而提升;体系在初始pH值为3.0~9.0范围内均能去除BPA,偏中性条件下其降解效果最佳;反应体系中的过硫酸根自由基(SO_(4)^(2-))和单线态氧(^(1)O_(2))对BPA的降解起主要作用。

ZnIn2S4@CNO多级纳米片用于光催化分解水制氢和还原CO2（英文）

光催化分解水制氢和还原CO2是太阳能利用领域的研究热点,对清洁能源的转化具有重要意义.石墨相氮化碳(CN)作为一种非金属半导体,是一种非常有开发潜力的光催化材料.然而限于其聚合物本质,光催化效率仍有待进一步提高.原位非金属掺杂可以利用元素电子结构调控电荷分布,优化光生电荷传输性能.同时,半导体复合,尤其是2D层状复合结构的构筑,可充分发挥2D半导体的优势,合适的能带交错有利于光生电荷的传输,可在一定程度上加速催化反应的进行.本文首先以草酸为氧掺杂源,采用二步煅烧法合成氧掺杂氮化碳纳米片催化剂(CNO).在二次煅烧和氧掺杂共同作用下,增大了CN层间距和多孔性,颗粒尺寸减小,同时增强了对光的吸光性,拓展了可见光吸收范围.接下来采用一步水热合成法得到ZnIn2S4@CNO(ZC)复合材料,在可见光照射下通过分解水制氢和CO2还原反应对复合材料进行光催化还原性能评价.采用X射线衍射(XRD)、透射电镜(TEM)、X射线光电子能谱(XPS)、荧光光谱(PL)、光电化学测试等方法对ZC进行详细的结构表征和分析.XRD和XPS结果表明,经过一步直接水热可得到层状ZC复合材料,高倍TEM进一步证实二者形成均一的2D异质复合材料.N2-吸附-脱附曲线表明,复合材料具有较大的比表面积和均一的孔结构分布,主要得益于O掺杂CNO纳米片的多孔性结构.光电性质测试结果表明,相比于CNO,复合材料具有降低的荧光发射强度和延长的荧光寿命,表明复合产物显著抑制了光生电荷的复合.电化学测试进一步表明,复合异质结的构筑有利于光生载流子的产生,同时降低了界面电荷转移电阻,提高了电荷迁移速率.因此,多孔2D异质结构的构筑对促进CN基半导体光催化还原具有重要作用.在可见光照射下(λ>400 nm),复合材料表现出优异的光催化还原性能,且随着CNO含量的增加催化活性不断提高,其中ZC 40%(CNO质量比40%)具有最佳的催化活性,其产氢速率达188.4μmol/h,约是ZnIn2S4和CNO的2.1倍.同时,光催化还原CO2测试表明,复合材料具有显著提高的CO和CH4产率,其中CO为主要反应产物.ZC40%的CO产生速率为12.69μmol/h,分别是ZnIn2S4和CNO的2.2倍和14.0倍.对催化剂进行连续光反应,结果表明,复合催化剂具有优异的结构稳定性和活性稳定性,能够持续发生光还原反应制取H2和CO.

Self-assembled S-scheme In_(2.77)S_(4)/K^(+)-doped g-C_(3)N_(4)photocatalyst with selective O_(2)reduction pathway for efficient H_(2)O_(2)production using water and air

The development of an efficient artificial H_(2)O_(2)photosynthesis system is a challenging work using H_(2)O and O_(2)as starting materials.Herein,3D In2.77S_(4)nanoflower precursor was in-situ deposited on K^(+)-doped g-C_(3)N_(4)(KCN)nanosheets using a solvothermal method,then In2.77S_(4)/KCN(IS/KCN)het-erojunction with an intimate interface was obtained after a calcination process.The investigation shows that the photocatalytic H_(2)O_(2)production rate of 50IS/KCN can reach up to 1.36 mmol g^(-1)h^(-1)without any sacrificial reagents under visible light irradiation,which is 9.2 times and 4.1 times higher than that of KCN and In2.77S_(4),respectively.The enhanced activity of the above composite can be mainly attributed to the S-scheme charge transfer route between KCN and In2.77S_(4)according to density functional theory calculations,electron paramagnetic resonance and free radical capture tests,leading to an expanded light response range and rapid charge separation at their interface,as well as preserving the active electrons and holes for H_(2)O_(2)production.Besides,the unique 3D nanostructure and surface hydrophobicity of IS/KCN facilitate the diffusion and transportation of O_(2)around the active centers,the energy barriers of O_(2)protonation and H_(2)O_(2)desorption steps are ef-fectively reduced over the composite.In addition,this system also exhibits excellent light harvesting ability and stability.This work provides a potential strategy to explore a sustainable H_(2)O_(2)photo-synthesis pathway through the design of heterojunctions with intimate interfaces and desired reac-tion thermodynamics and kinetics.