复合半导体光催化剂p-CoO/n-CdS的制备、表征及光催化性能

以醋酸镉、十二硫醇、硬脂酸和醋酸钴等为原料,采用新方法制备了CdS和一系列p-CoO/n-CdS复合半导体光催化剂.用X射线衍射(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)、N2吸附-脱附和紫外-可见漫反射光谱(UV-Vis DRS)等对产物进行了表征.结果表明,p-CoO/n-CdS复合半导体中,CoO粒子紧密结合在CdS颗粒上,CdS的颗粒粒径在100 nm左右,为六方纤锌矿晶型,CoO的颗粒粒径在10 nm左右,颗粒粒径分布均匀.p-CoO/n-CdS的UV-Vis DRS分析结果表明,在400-550 nm范围内都有一强吸收带,属于CdS在可见光区的特征吸收.用光催化降解甲基橙测试了光催化性能,结果表明,p-CoO/n-CdS光催化活性是CdS光催化活性的2.2倍左右.光腐蚀测试结果表明,CdS的光腐蚀速率是p-CoO/n-CdS中CdS光腐蚀速率的2倍以上,说明CoO与CdS复合对CdS的光腐蚀具有明显的抑制作用.     

ZnIn2S4纳米片与WO3纳米棒构建3D结构的S型异质结用于可见光光催化分解水产氢(英文)

氢气是一种清洁能源,利用太阳能进行光催化分解水产氢,因为节能和环保,吸引了国内外学者的广泛关注.但是,半导体光催化材料普遍存在可见光吸收范围窄和光生载流子易复合等问题,导致光催化效率不高.半导体耦合是拓展光吸收范围,并促进光生载流子空间分离的有效策略之一.能带相互交错的两种半导体复合,可以形成传统的Ⅱ型异质结,但是这种耦合方式削弱了光生电荷的氧化还原能力.相对传统Ⅱ型异质结光催化材料的不足,余家国教授提出了S型异质结的概念,它通常由两种n型半导体光催化剂组成,其中能带位置较高的为还原型光催化剂(RP),能带位置较低的是氧化型光催化剂(OP).形成S型异质结的关键是接触界面处存在由RP指向OP的内电场.受内建电场的驱动,S型异质结界面电子和空穴的流向与传统Ⅱ型光催化剂完全不同.由于保留了光生电子和空穴具有较强的还原和氧化能力,S型异质结在热力学上更有利于光催化氧化与还原反应.本文以硫代乙酰胺为硫源,采用低温溶剂热法(乙二醇中110℃反应2 h),在氧化型光催化剂(1D的WO₃纳米棒)表面原位生长还原型光催化剂(2D的ZnIn₂S₄     

Z-机制WO3(H2O)0.333/Ag3PO4复合材料的制备及其增强光催化活性和稳定性

Ag_3PO_4由于具有独特的活性而被广泛应用于光催化领域.然而,由于其光生电子和空穴的快速复合, Ag_3PO_4的光催化性能在几个循环之后显著下降,光腐蚀限制了它的实际应用.因此,亟需设计一种新型的复合光催化剂来抑制电子空穴对的快速复合.而Z型复合光催化剂可综合不同光催化剂的优点,克服单一光催化剂的缺点.Z方案体系使用两个窄带隙的催化剂取代宽带隙的光催化剂,从而可以捕获更多的光子.并且光催化剂的氧化还原反应分开进行,可以有效地防止电子和空穴的复合,从而大大提高复合光催化剂的性能.本文通过微波水热法和简单搅拌法成功地制备了Z机制WO_3(H_2O)_(0.333)/Ag_3PO_4复合材料.采用X射线衍射、扫描电子显微镜、X射线光电子能谱、N2吸附-解吸等温线、比表面积测定、紫外-可见光谱和光电流曲线等方法对WO_3(H_2O)_(0.333)/Ag_3PO_4复合材料进行了表征.通过这些表征,我们确定了所研究的光催化剂物相高度匹配;确定了光催化剂的形貌:确定了复合光催化剂是复合物,而不是简单的混合物;确定了光催化剂中光生电子和空穴的结合、分离效率;研究了光催化剂的吸收边以及带隙.光催化降解测试发现, WO_3(H_2O)_(0.333)/Ag_3PO_4复合材料在可见光下表现出优异的催化性能,这主要归因于WO_3(H_2O)_(0.333)/Ag_3PO_4的协同作用.其中15%WO_3(H_2O)_(0.333)/Ag_3PO_4的光催化活性最高,在4min内几乎将30m L20mol/L的次甲基蓝完全降解.并且,复合材料的稳定性也得到很大提升.经过5次循环反应后, 15%WO_3(H_2O)_(0.333)/Ag_3PO_4的降解效率仍可以维持在88.2%.相比之下,纯Ag_3PO_4的降解效率仅为20.2%.这表明添加WO_3(H_2O)_(0.333)可以显著提高Ag_3PO_4的耐光腐蚀性.最后,我们详细研究了Z-机制机理.在可见光照射下, Ag_3PO_4和WO_3(H_2O)_(0.333)的表面产生电子-空穴对.WO_3(H_2O)_(0.333)的光生电子首先转移到其导带,然后迁移到Ag_3PO_4的价带中与空穴结合.因此, Ag_3PO_4的光生电子和空穴被有效分离,光生电子连续转移到Ag_3PO_4的导带界面.这样, Ag_3PO_4的导带界面上积累了大量的电子,并且在WO_3(H_2O)_(0.333)的价带界面中积累了大量的空穴.在空穴的作用下,–OH与h~+反应生成·OH,·OH与污染物甲基蓝反应生成CO_2和H_2O.同时,大量的H~+和O_2与电子反应,在Ag_3PO_4的导带界面处产生H_2O_2.之后, H_2O_2与电子反应产生·OH,·OH与甲基蓝反应形成CO_2和H_2O.这样,光生电子和空穴连续分离,大大提高了光催化反应速度,最终催化剂的光催化活性得到极大的提高.     

Ag3PO4/Ag2CO3 p-n异质结复合光催化剂的制备及增强的可见光催化性能

半导体光催化氧化技术作为一种“绿色技术”,被广泛应用于环境污染物治理和太阳能转化领域.高效、稳定、可回收利用的催化剂的开发是光催化技术发展的一个重要方向. Ag系半导体光催化剂因在可见光分解水制氢及降解有机污染物等方面表现出优异的催化性能而广受关注.然而,该催化剂失活快制约了其应用.因此,提高Ag系半导体材料的光催化稳定性成为近年来研究的一个热点.研究发现,在半导体的表面或者界面形成p–n异质结是提高催化剂光催化性能和稳定性的有效途径.理论上讲,当p型半导体和n型半导体形成p–n结以后,在两种半导体接触边缘的附近处存在着正、负空间电荷分列两边的偶极层,产生了从n型半导体指向p型半导体的内建电场.内建电场的存在使得p型半导体与n型半导体之间产生了电位差,即内建电势差.这种电势差能够有效促进电子和空穴的分离,达到光生电子和空穴对分离、转移和传递的目的,从而抑制电子和空穴的复合,提高光催化效率. Ag2CO3是p型半导体,其导带为0.21 eV,价带为2.83 eV; Ag3PO4是n型半导体,其导带为0.43 eV,价带为2.86 eV.两者能带结构匹配,能形成p–n异质结.因此,本文采用简单的共沉淀法,制备了不同比例的Ag3PO4/Ag2CO3复合光催化剂,并通过X射线衍射、透射电镜、X射线光电子能谱、紫外-可见漫反射光谱以及瞬态光电压谱等对其进行了表征.透射电镜照片显示,粒径较小的Ag3PO4颗粒均匀的分布在粒径较大的Ag2CO3周围. P元素和C元素的摩尔比接近于投料比. Ag3PO4/Ag2CO3复合催化剂的吸收光谱体现出两种催化剂的混合特征,在可见光区的吸收强度增加.瞬态光电压表征不仅证实了Ag2CO3是p型半导体, Ag3PO4是n型半导体,更说明了40%-Ag3PO4/Ag2CO3复合光催化剂的载流子寿命较长.罗丹明B(RhB)的降解实验证实40%-Ag3PO4/Ag2CO3(Ag3PO4与Ag2CO3的摩尔比为40%：60%)复合催化剂的光催化效率最高,500 W氙灯(附加420 nm截止波长的滤光片)照射15 min后, RhB就能被完全降解,而纯的Ag3PO4和Ag2CO3对RhB的降解率只有40%和10%.循环实验发现,前两次循环中由于单质银的生成导致催化剂活性下降,但从第三次循环开始其催化活性趋于稳定.此外,还通过添加草酸钠(空穴的清除剂)、异丙醇(羟基自由基的清除剂)和对苯醌(超氧自由基的淬灭剂)等来判断光催化过程中起主要作用的活性自由基.实验证实空穴是Ag3PO4/Ag2CO3光催化剂在降解RhB过程中产生的主要活性自由基物种. Ag3PO4/Ag2CO3光催化剂相对于单纯的Ag3PO4和Ag2CO3有更高的空穴产生能力.当可见光照射到复合催化剂表面时, Ag2CO3导带上的激发电子能够快速转移到Ag3PO4的导带上,同时Ag3PO4价带上的光生空穴能够快速转移到Ag2CO3的价带上. p–n结的形成提高了光生电子和空穴的分离效率,抑制了电子和空穴的再结合,因此,复合光催化剂光催化降解效率提高.综上所述, Ag3PO4/Ag2CO3之间能形成有效p–n结,40%-Ag3PO4/Ag2CO3复合光催化剂表现出最佳的光催化性能.     

Ag_3PO_4/Ag_2CO_3p–n异质结复合光催化剂的制备及增强的可见光催化性能（英文）

半导体光催化氧化技术作为一种"绿色技术",被广泛应用于环境污染物治理和太阳能转化领域.高效、稳定、可回收利用的催化剂的开发是光催化技术发展的一个重要方向.Ag系半导体光催化剂因在可见光分解水制氢及降解有机污染物等方面表现出优异的催化性能而广受关注.然而,该催化剂失活快制约了其应用.因此,提高Ag系半导体材料的光催化稳定性成为近年来研究的一个热点.研究发现,在半导体的表面或者界面形成p–n异质结是提高催化剂光催化性能和稳定性的有效途径.理论上讲,当p型半导体和n型半导体形成p–n结以后,在两种半导体接触边缘的附近处存在着正、负空间电荷分列两边的偶极层,产生了从n型半导体指向p型半导体的内建电场.内建电场的存在使得p型半导体与n型半导体之间产生了电位差,即内建电势差.这种电势差能够有效促进电子和空穴的分离,达到光生电子和空穴对分离、转移和传递的目的,从而抑制电子和空穴的复合,提高光催化效率.Ag2CO3是p型半导体,其导带为0.21 e V,价带为2.83 e V;Ag3PO4是n型半导体,其导带为0.43 e V,价带为2.86 e V.两者能带结构匹配,能形成p–n异质结.因此,本文采用简单的共沉淀法,制备了不同比例的Ag3PO4/Ag2CO3复合光催化剂,并通过X射线衍射、透射电镜、X射线光电子能谱、紫外-可见漫反射光谱以及瞬态光电压谱等对其进行了表征.透射电镜照片显示,粒径较小的Ag3PO4颗粒均匀的分布在粒径较大的Ag2CO3周围.P元素和C元素的摩尔比接近于投料比.Ag3PO4/Ag2CO3复合催化剂的吸收光谱体现出两种催化剂的混合特征,在可见光区的吸收强度增加.瞬态光电压表征不仅证实了Ag2CO3是p型半导体,Ag3PO4是n型半导体,更说明了40%-Ag3PO4/Ag2CO3复合光催化剂的载流子寿命较长.罗丹明B(Rh B)的降解实验证实40%-Ag3PO4/Ag2CO3(Ag3PO4与Ag2CO3的摩尔比为40%:60%)复合催化剂的光催化效率最高,500 W氙灯(附加420 nm截止波长的滤光片)照射15 min后,RhB就能被完全降解,而纯的Ag3PO4和Ag2CO3对RhB的降解率只有40%和10%.循环实验发现,前两次循环中由于单质银的生成导致催化剂活性下降,但从第三次循环开始其催化活性趋于稳定.此外,还通过添加草酸钠(空穴的清除剂)、异丙醇(羟基自由基的清除剂)和对苯醌(超氧自由基的淬灭剂)等来判断光催化过程中起主要作用的活性自由基.实验证实空穴是Ag3PO4/Ag2CO3光催化剂在降解RhB过程中产生的主要活性自由基物种.Ag3PO4/Ag2CO3光催化剂相对于单纯的Ag3PO4和Ag2CO3有更高的空穴产生能力.当可见光照射到复合催化剂表面时,Ag2CO3导带上的激发电子能够快速转移到Ag3PO4的导带上,同时Ag3PO4价带上的光生空穴能够快速转移到Ag2CO3的价带上.p–n结的形成提高了光生电子和空穴的分离效率,抑制了电子和空穴的再结合,因此,复合光催化剂光催化降解效率提高.综上所述,Ag3PO4/Ag2CO3之间能形成有效p–n结,40%-Ag3PO4/Ag2CO3复合光催化剂表现出最佳的光催化性能.     

1D/2D TiO2/ZnIn2S4S型异质结光催化剂及其高效制氢性能

通过半导体催化剂利用太阳能分解水制氢被认为是解决人类面临的环境问题和能源危机的有效途径.在众多的半导体光催化剂中,TiO₂由于其良好的光化学稳定性、无毒性、丰富的形貌以及低廉的价格,在光催化制氢领域备受关注.然而TiO₂的内在缺陷,如较宽的带隙、较窄的光响应范围,光生电子空穴对的快速复合,极大限制了其太阳能制氢效率.构建异质结结构被认为是解决以上问题的一个有效方法,通过将TiO₂与另一个半导体复合可以提升催化剂对太阳光的吸收范围,也可降低光生电子空穴对的复合速率.但构建一个成功的异质结结构不仅要满足上述的要求,还需要保留异质结催化剂体系中光生电子和空穴的氧化还原能力.研究表明,S型异质结是将两个具有合适能带结构的半导体进行耦合,由于费米能级的差异,两个半导体间将发生电子转移,从而引起能带弯曲并形成内建电场.光照条件下,具有较弱还原能力的光生电子在内建电场和能带弯曲的作用下与较弱氧化能力的光生空穴复合,实现异质结催化剂体系中各个半导体内部光生载流子有效分离的目标,同时保留了异质结催化剂体系中较强氧化能力和较强还原能力的光生电子和空穴,进而实现光催化活性的提高.本文采用水热合成方法,将具有更强还原能力和可见光响应特性的半导体(ZnIn₂S₄)原位生长在TiO₂纳米纤维表面,构建了1D/2DTiO₂/ZnIn₂S₄S型异质结光催化剂.最优比例的TiO₂/ZnIn₂S₄复合材料表现出优越的光催化制氢活性(6.03mmol/h/g),分别是纯TiO₂和纯ZnIn₂S₄制氢活性的3.7倍和2倍.TiO₂/ZnIn₂S₄复合材料光催化活性的提高可以归因于紧密的异质结界面、光生载流子的有效分离、丰富的反应活性位点以及增强的光吸收能力.通过原位XPS和DFT计算研究了异质结内部光生电子的转移机制.结果表明,在光照条件下电子由TiO₂向ZnIn₂S₄迁移,遵循了S型异质结内部电子的转移机制,实现了TiO₂和ZnIn₂S₄内部光生载流子的有效分离,同时保留了具有较强还原能力的ZnIn₂S₄价带电子和较强氧化能力的TiO₂导带空穴,从而显著提升光催化制氢效率.综上,本文制备的TiO₂/ZnIn₂S₄S型异质结光催化剂很好地克服了TiO₂在光催化制氢领域所面临的诸多障碍,为设计和制备高效异质结光催化剂提供了新的思路.     

CdS/FeP复合光催化材料界面结构与性质的理论研究

构建同质异相或异质结构是提高光催化材料性能的有效途径之一,尤其是对于CdS这类具有光腐蚀的材料,这种方法还能起到提高光催化材料稳定性的作用。因此目前制备CdS基复合光催化材料得到了广泛的研究,但是目前对其中的一些基本问题和关键因素仍需要进一步探讨和解释。本文采用第一性原理方法对CdS/FeP复合光催化材料中异质结构的界面微观结构和性质进行深入研究。计算结果表明,由于在界面上部分悬挂键被饱和,界面模型呈现出与体相或表面模型不同的电子结构特征,并且有界面态的存在。在CdS/FeP异质结构的界面处,CdS和FeP的能带都相对向下移动,而且FeP的能带（费米能级）插入到CdS的导带下方;同时在界面达到平衡态之后,异质结构的内建电场由FeP层指向CdS层,因而能够实现光生电子-空穴对在CdS/FeP界面处的空间有效分离,这对于光催化性能的增强极其有利。此外,构建CdS/FeP异质结构也能够进一步增强CdS在可见光区的光吸收。本文研究结果为构建具有异质结构的高效复合光催化材料提供了机理解释和理论支持。     

集成二维层状CdS/WO3S型异质结及金属化Ti3C2MXene基欧姆结高效光催化产氢

开发低成本的半导体光催化剂以实现可见光下高效、持久的光催化分解水产氢是一个非常具有挑战性的课题.近年来,具有高产氢活性的CdS光催化剂引起了人们的研究兴趣.但是光生电子-空穴对快速复合、反应活性位点不足以及严重的光腐蚀等问题,严重地制约了CdS在光催化领域的实际应用.构建S型异质结和负载助催化剂被认为是促进光生电子空穴分离和加速产氢动力学的有效策略.本文通过在低成本的WO₃和Ti₃C₂MXene(MX)纳米片上生长CdS纳米片,设计并构建了具有二维耦合界面的2D/2D/2D层状异质结光催化剂,以实现高效的可见光光催化分解水产氢.首先通过水热煅烧和刻蚀的方法分别制备了WO₃和MX纳米片,然后以乙酸镉和硫脲为原料在乙二胺溶剂中通过水热法合成了MX-CdS/WO₃层状异质结光催化剂.在可见光下,以乳酸为牺牲剂测试了光催化剂的产氢活性且经过4次连续的循环反应,MX-CdS/WO₃体系展现出良好的活性及稳定性.在可见光的照射下,MX-CdS/WO₃层状异质结光催化剂最高的可见光光催化分解水产氢速率达到了27.5 mmol/g/h,是纯CdS纳米片的11倍.与此同时,在450 nm的光照下,表观量子效率达到了12.0%.为了深入探讨其高效产氢机理,通过X射线衍射、X射线光电子能谱、原子力显微镜、透射电镜、高分辨电子显微镜等对MX-CdS/WO₃体系的组成和结构进行分析.结果表明,实验成功地合成了CdS,WO₃和MX三种纳米片及其复合材料.通过紫外-可见漫反射光谱研究了样品材料的光吸收能力.通过表面光电压、稳态及瞬态荧光光谱等研究了材料的电荷载流子复合和转移行为,发现MX-CdS/WO₃的光生电子空穴对相比与纯CdS或者二元复合材料具有更高的分离效率.UPS和ESR等表征结果说明,材料内部电场的方向和在光照条件下光生载流子的迁移方向,从而证实了S型异质结和欧姆结的成功构建.综上,在MX-CdS/WO₃光催化剂体系中,S型异质结形成较强的界面电场能够有效促进CdS纳米片与WO₃纳米片之间光生电子-空穴对的分离.同时,二维Ti₃C₂MXene纳米片作为辅助催化剂,通过与CdS/WO₃纳米片构建欧姆结,进而提供大量的电子转移途径和更多的析氢反应活性位点,使得CdS光催化剂的光催化活性和稳定性得到了很大的提升.通过构建S型内建电场、欧姆结和2D/2D界面可以协同提高CdS纳米片的光催化性能,从而加速光生电子在异质结中的分离和利用.本文所采用基于S型异质结与欧姆结基助催化剂之间的耦合策略可以作为一种通用策略扩展到其它传统半导体光催化剂的改性中,从而推进高效光催化产氢材料的有效合成.     

CdS/石墨烯纳米复合物的可见光催化效率和抗光腐蚀行为

制备了一系列CdS纳米晶/石墨烯(CdS/GR)复合物,并在可见光照条件下评价了其光催化降解亚甲基蓝的光催化效率和抗光腐蚀行为. 研究表明,石墨烯的引入加速了CdS纳米晶(NCs)光生电子的迁移速率,抑制了其光生电子-空穴的复合,有效改善了其光催化降解有机污染物的性能. CdS/GR复合物中的石墨烯含量显著影响其光催化效率,其中石墨烯含量为4.6%的光催化剂效率最高,其光电流是CdS NCs的2.3倍. 利用光电化学和X射线衍射技术进一步证实,石墨烯的引入抑制了CdS NCs光腐蚀的发生,提高了CdS/GR复合物的光催化稳定性.     

不同半导体体系中磷化镍光催化甲酸分解的助催化作用

研究了在不同的半导体体系(TiO₂, CdS和C₃N₄)中, Ni₂P光催化甲酸(HCOOH)分解制氢的助催化效应. 作为助催化剂, Ni₂P与3种半导体形成的复合光催化剂均表现出良好的HCOOH分解制氢活性. Ni₂P/TiO₂, Ni₂P/CdS, Ni₂P/C₃N₄ 3种光催化剂最优的产氢活性分别为41.69, 22.45和47.67 μmol·mg^-1·h^-1, 分别为纯TiO₂, CdS和C₃N₄的3.8倍、 10倍和210倍, 表明Ni₂P在光催化HCOOH分解制氢体系中具有普适性. 研究了光催化HCOOH分解制氢的机理, Ni₂P的加入使光生电子从半导体转移至Ni₂P, 提高了光生电子-空穴对的分离效率; Ni₂P还促进了活性物种·OH的生成, 提高了光催化HCOOH分解的产氢速率.     

SiC/Pt/CdS纳米棒Z型异质结的制备及其高效光催化产氢性能

In this study, a novel silicon carbide/platinum/cadmium sulfide (SiC/Pt/CdS) Z-scheme heterojunction nanorod is constructed using a simple chemical reduction-assisted hydrothermal method, in which Pt nanoparticles are anchored at the interface of SiC nanorods and CdS nanoparticles to induce an electron-hole pair transfer along the Z-scheme transport path. Multiple characterization techniques are used to analyze the structure, morphology, and properties of these materials. X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS) results show that the SiC/Pt/CdS materials with good crystal structure are successfully synthesized. Transmission electron microscopy reveals that Pt nanoparticles grow between the interfaces of SiC nanorods and CdS nanoparticles. UV-Vis diffuse reflectance spectroscopy shows that the as-prepared Z-scheme heterojunction samples have a wider light absorption range in comparison with pristine CdS materials. Photoluminescence spectroscopy and the transient photocurrent response further demonstrate that the SiC/Pt/CdS nanorod sample with an optimal molar ratio possesses the highest electron-hole pair separation efficiency. The loading amount of CdS on the surface of SiC/Pt nanorods is effectively adjusted by controlling the molar ratio of SiC and CdS to achieve the optimal performance of the SiC/Pt/CdS nanorod photocatalysts. The optimal H₂ evolution capacity is achieved at SiC : CdS = 5 : 1 (molar ratio) and the maximum H₂ evolution rate reaches a high value of 122.3 µmol·h⁻¹. In addition, scanning electron microscopy, XRD, and XPS analyses show that the morphology and crystal structure of the SiC/Pt/CdS photocatalyst remain unchanged after three cycles of activity testing, indicating that the SiC/Pt/CdS nanocomposite has a stable structure for H₂ evolution under visible light. To prove the Z-scheme transfer mechanism of electron-hole pairs, selective photo-deposition technology is used to simultaneously carry out the photo-reduction deposition of Au nanoparticles and photo-oxidation deposition of Mn₃O₄ nanoparticles in the photoreaction. The experimental results indicate that during photocatalysis, the electrons in the conduction band of CdS participate mainly in the reduction reaction, and the holes in the valence band of SiC are more likely to undergo the oxidation reaction. The electrons in the conduction band of SiC combine with the holes in the valence band of CdS to form a Z-scheme transport path. Therefore, a possible Z-scheme charge migration path in SiC/Pt/CdS nanorods during photocatalytic H₂ production is proposed to explain the enhancement in the activity. This study provides a new strategy for synthesizing a Z-scheme photocatalytic system based on SiC nanorods. Based on the characterization results, it is determined that SiC/Pt/CdS nanocomposites are highly efficient, inexpensive, easy to prepare, and are stable structures for H₂ evolution under visible light with outstanding commercial application prospects.     

新型S型CdS-BiVO4异质结光电极的构筑及产氢性能研究

通过化学浴和连续离子层沉积法构筑了BiVO₄/CdS和CdS/BiVO₄两种S型异质结薄膜光电极. 利用扫描电子显微镜(SEM)、 X射线衍射(XRD)、 紫外-可见吸收光谱(UV-Vis)以及电化学阻抗谱(EIS)对其形貌、 结构和光电性能进行了表征, 测试了两种薄膜电极的光催化和光电催化产氢性能. 结果表明, CdS和BiVO₄之间形成S型异质结, BiVO₄/CdS表现出最佳的光催化产氢性能, 而CdS/BiVO₄表现出最佳的光电催化产氢性能. 借助表面光电压技术探究了两种薄膜电极中S型异质结内建电场的形成过程和载流子传输的机制.     

全有机S型异质结PDI-Ala/S-C3N4光催化剂增强光催化性能

Organic photocatalysts have attracted attention owing to their suitable redox band positions, low cost, high chemical stability, and good tunability of their framework and electronic structure. As a novel organic photocatalyst, PDI-Ala (N, N'-bis(propionic acid)-perylene-3, 4, 9, 10-tetracarboxylic diimide) has strong visible-light response, low valence band position, and strong oxidation ability. However, the low photogenerated charge transfer rate and high carrier recombination rate limit its application. Due to the aromatic heterocyclic structure of g-C₃N₄ and large delocalized π bond in the planar structure of PDI-Ala, g-C₃N₄ and PDI-Ala can be tightly combined through π–π interactions and N―C bond. The band structure of sulfur-doped g-C₃N₄ (S-C₃N₄) matched well with PDI-Ala than that with g-C₃N₄. The electron delocalization effect, internal electric field, and newly formed chemical bond jointly promote the separation and migration of photogenerated carriers between PDI-Ala and S-C₃N₄. To this end, a novel step-scheme (S-scheme) heterojunction photocatalyst comprising organic semiconductor PDI-Ala and S-C₃N₄ was prepared by an in situ self-assembly strategy. Meanwhile, PDI-Ala was self-assembled by transverse hydrogen bonding and longitudinal π–π stacking. The crystal structure, morphology, valency, optical properties, stability, and energy band structure of the PDI-Ala/S-C₃N₄ photocatalysts were systematically analyzed and studied by various characterization methods such as X-ray diffraction, transmission electron microscopy, energy dispersive X-ray spectrometry, X-ray photoelectron spectroscopy, ultraviolet visible diffuse reflectance spectroscopy, electrochemical impedance spectroscopy, and Mott-Schottky curve. The work functions and interface coupling characteristics were determined using density functional theory. The photocatalytic activities of the synthesized photocatalyst for H₂O₂ production and the degradation of tetracycline (TC) and p-nitrophenol (PNP) under visible-light irradiation are discussed. The PDI-Ala/S-C₃N₄ S-scheme heterojunction with band matching and tight interface bonding accelerates the intermolecular electron transfer and broadens the visible-light response range of the heterojunction. In addition, in the processes of the PDI-Ala/S-C₃N₄ photocatalytic degradation reaction, a variety of active species (h⁺, ·O₂^-, and H₂O₂) were produced and accumulated. Therefore, the PDI-Ala/S-C₃N₄ heterojunction exhibited enhanced photocatalytic performance in the degradation of TC, PNP, and H₂O₂ production. Under visible-light irradiation, the optimum 30%PDI-Ala/S-C₃N₄ removed 90% of TC within 90 min. In addition, 30%PDI-Ala/S-C₃N₄ displayed the highest H₂O₂ evolution rate of 28.3 μmol·h^-1·g^-1, which was 2.9 and 1.6 times higher than those of PDI-Ala and S-C₃N₄, respectively. These results reveal that the all organic photocatalyst comprising PDI-based supramolecular and S-C₃N₄ can be efficiently applied for the degradation of organic pollutants and production of H₂O₂. This work not only provides a novel strategy for the design of all organic S-scheme heterojunctions but also provides a new insight and reference for understanding the structure–activity relationship of heterostructure catalysts with effective interface bonding.      

可见光光解H2S产H2的研究——Rh2O3/CdS悬浮体系中硫化物水溶液的光解

在半导体粉末悬浮体系光解水研究中,最常用的半导体粉末是CdS和TiO₂。前者光谱响应好,可见光即可激发,但易于光腐蚀;后者稳定性好,但禁带宽,仅紫外光可激发。从不同角度改善这二者的性能,一直为人们所关注。在CdS上沉积RuO₂,并选择适宜的反应以抑制CdS的光腐蚀^[1];应用掺杂的方法,使TiO₂的光谱响应扩展至可见区,已取得进展。     

高催化活性2D/2D Ti3C2/Bi4O5Br2纳米片异质结的构建及其可见光催化去除NO

This study concentrated on the production of a two-dimensional and two-dimensional (2D/2D) Ti₃C₂/Bi₄O₅Br₂ heterojunction with a large interface that applied as one of the novel visible-light-induced photocatalyst via the hydrothermal method. The obtained photocatalysts enhanced the photocatalytic efficiency of the NO removal. The crystal structure and chemical state of the composites were characterized using X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS). The results showed that Ti₃C₂, Bi₄O₅Br₂, and Ti₃C₂/Bi₄O₅Br₂ were successfully synthesized. The experimental results of scanning electron microscopy (SEM) and transmission electron microscopy (TEM) showed that the prepared samples had a 2D/2D nanosheet structure and large contact area. This structure facilitated the transfer of electrons and holes. The solar light absorptions of the samples were evaluated using the UV-Vis diffuse reflectance spectra (UV-Vis DRS). It was found that the absorption band of Ti₃C₂/Bi₄O₅Br₂ was wider than that of Bi₄O₅Br₂. This represents the electrons in the Ti₃C₂/Bi₄O₅Br₂ nanosheet composites were more likely to be excited. The photocatalytic experiments showed that the 2D/2D Ti₃C₂/Bi₄O₅Br₂ composite with high photocatalytic activity and stability. The photocatalytic efficiency of pure Bi₄O₅Br₂ for the NO removal was 30.5%, while for the 15%Ti₃C₂/Bi₄O₅Br₂ it was 57.6%. Moreover, the catalytic reaction happened in a short period. The concentration of NO decreased exponentially in the first 5 min, which approximately reached the final value. Furthermore, the stability of 15%Ti₃C₂/Bi₄O₅Br₂ was favorable: the catalytic rate was approximately 50.0% after five cycles of cyclic catalysis. Finally, the scavenger experiments, electron spin resonance spectroscopy (ESR), transient photocurrent response, and surface photovoltage spectrum (SPS) were applied to analyze the photocatalytic mechanism of the composite. The results indicated that the 2D/2D heterojunction Ti₃C₂/Bi₄O₅Br₂ improved the separation rate of the electrons and holes, thus enhancing the photocatalytic efficiency. In the photocatalytic reactions, the photogenerated electrons (e⁻) and superoxide radical (·O₂⁻) were critical active groups that had a significant role in the oxidative removal of NO. The in situ Fourier-transform infrared spectroscopy (in situ FTIR) showed that the photo-oxidation products were mainly NO₂⁻ and NO₃⁻. Based on the above experimental results, a possible photocatalytic mechanism was proposed. The electrons in Bi₄O₅Br₂ were excited by visible light. They jumped from the valence band (VB) of Bi₄O₅Br₂ to the conduction band (CB). Then, the photoelectrons transferred from the CB of Bi₄O₅Br₂ to the Ti₃C₂ surface, which significantly promoted the separation of the electron-hole pairs. Therefore, the photocatalytic efficiency of Ti₃C₂/Bi₄O₅Br₂ on NO was significantly improved. This study provided an effective method for preparing 2D/2D Ti₃C₂/Bi₄O₅Br₂ nanocomposites for the photocatalytic degradation of environmental pollutants, which has great potential in solving energy stress and environmental pollution.     

Enhanced Charge Separation of α-Bi2O3-BiOI Hollow Nanotube for Photodegradation Antibiotic Under Visible Light

It is highly desirable to exploit semiconductor materials with high photocatalytic degradation activity, especially bismuth oxyhalide semiconductor photocatalysts with special layered structure and suitable bandgap width. The low utilization rate of visible light and high recombination rate of photogenerated electron-hole of BiOI photocatalyst severely restrict its development. Herein, a heterojunction photocatalyst of α-Bi₂O₃-BiOI hollow nanotube was prepared by electrospinning method, solvothermal method and ion-exchange method. The α-Bi₂O₃-BiOI(BB-4, the stirring time of Bi₂O₃ in KI solution was 4 h) exhibited the best photocatalytic performance towards degrading the tetracycline hydrochloride(TC) solution, which could remove 85% of TC(10 mg/L) in 2 h under visible light irradiation. The estimated k_TC of α-Bi₂O₃-BiOI(BB-4) was ca. 3.9 and 1.8 times as much as that of α-Bi₂O₃ and pure BiOI, respectively. It indicated that the formation of α-Bi₂O₃-BiOI heterojunction can significantly improve the separation efficiency of photogenerated electron-hole pairs, therefore the photocatalytic ability was enhanced. Furthermore, a corresponding photocatalytic mechanism was proposed that ^·O₂^- radical and holes are the main active components in the photodegradation through trapping experiment.     

多孔纳米CoFe2O4的制备及其对高氯酸铵的热分解催化性能

采用胶晶模板法制备出具有三维多孔结构的纳米CoFe₂O₄。利用X射线衍射仪(XRD)、傅里叶变换红外(FT-IR)光谱仪、扫描电镜(SEM)、透射电镜(TEM)和N₂吸附-脱附对样品的晶型和形貌结构等进行表征,采用差示扫描量热法(DSC)对比研究多孔纳米CoFe₂O₄和球形纳米CoFe₂O₄对高氯酸铵(AP)的热分解性能的影响,并考察这两种催化剂对AP催化热分解的动力学参数。结果显示,制备出的多孔纳米CoFe₂O₄样品具有典型的尖晶石结构,孔径约200 nm;比表面积明显高于40 nm球形CoFe₂O₄,达到55.646 m²·g^-1。DSC测试结果表明：多孔纳米CoFe₂O₄的加入促进了AP的热分解,最高使AP的高温分解峰温降低91.46℃,能量释放最高达1120.88 J·g^-1,是纯AP分解放热量的2.3倍;多孔纳米CoFe₂O₄具有较高的比表面积,能提高催化反应的接触面积,使AP的高温分解峰温度更低,反应活化能较小,从而表现出比球形纳米CoFe₂O₄更高的催化活性。此外,对多孔纳米CoFe₂O₄催化AP的热分解机理进行初步探索,纳米多孔催化剂对气态中间产物的作用促进了AP的热分解。     

纳米CoFe2O4/GNS负极制备及其电化学性能研究

采用溶剂热法一步合成纳米尺寸CoFe₂O₄/GNS复合材料（直径约为15 nm）,其颗粒尺寸均一,且均匀分散于石墨烯表面. 电化学测试结果表明,该复合物电极具有良好的循环和倍率性能,500 mA·g^-1电流密度下100周期循环比容量稳定在709 mAh·g^-1, 容量保持率高达95.8%;2 A·g^-1电流密度,其比容量仍高达482 mAh·g^-1.     

Cu2+改性g-C3N4光催化剂的光催化性能

Photocatalytic technology can effectively solve the problem of increasingly serious water pollution, the core of which is the design and synthesis of highly efficient photocatalytic materials. Semiconductor photocatalysts are currently the most widely used photocatalysts. Among these is graphitic carbon nitride (g-C₃N₄), which has great potential in environment management and the development of new energy owing to its low cost, easy availability, unique band structure, and good thermal stability. However, the photocatalytic activity of g-C₃N₄ remains low because of problems such as wide bandgap, weakly absorb visible light, and the high recombination rate of photogenerated carriers. Among various modification strategies, doping modification is an effective and simple method used to improve the photocatalytic performance of materials. In this work, Cu/g-C₃N₄ photocatalysts were successfully prepared by incorporating Cu²⁺ into g-C₃N₄ to further optimize photocatalytic performance. At the same time, the structure, morphology, and optical and photoelectric properties of Cu/g-C₃N₄ photocatalysts were analyzed by X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), scanning electron microscopy, UV-Vis diffuse reflectance spectroscopy (DRS), and photoelectric tests. XRD and XPS were used to ensure that the prepared photocatalysts were Cu/g-C₃N₄ and the valence state of Cu was in the form of Cu²⁺. Under visible light irradiation, the photocatalytic activity of Cu/g-C₃N₄ and pure g-C₃N₄ photocatalysts were investigated in terms of the degradation of RhB and CIP by comparing the amount of introduced copper ions. The experimental results showed that the degradation ability of Cu/g-C₃N₄ photocatalysts was stronger than that of pure g-C₃N₄. The N₂ adsorption-desorption isotherms of g-C₃N₄ and Cu/g-C₃N₄ demonstrated that the introduction of copper had little effect on the microstructure of g-C₃N₄. The small difference in specific surface area indicates that the enhanced photocatalytic activity may be attributed to the effective separation of photogenerated carriers. Therefore, the enhanced photocatalytic degradation of RhB and CIP over Cu/g-C₃N₄ may be due to the reduction of carrier recombination rate by copper. The photoelectric test showed that the incorporation of Cu²⁺ into g-C₃N₄ could reduce the electron-hole recombination rate of g-C₃N₄ and accelerate the separation of electron-hole pairs, thus enhancing the photocatalytic activity of Cu/g-C₃N₄. Free radical trapping experiments and electron spin resonance indicated that the synergistic effect of superoxide radicals (O₂^•−), hydroxyl radicals (•OH) and holes could increase the photocatalytic activity of Cu/g-C₃N₄ materials.     

Bi4V2O11/石墨烯异质结光催化剂的制备及其在降解抗体污染物中应用

发展和设计高效、廉价和稳定的光催化剂用于抗生素污染物降解仍然存在巨大的挑战。 本文通过一种便捷的水热方法制备了Bi₄V₂O₁₁/石墨烯复合材料并用于可见光下抗生素污染物光催化降解。 通过自由基追踪实验,确认了光催化降解过程中活性物质为h⁺和·OH基团。 根据实验结果,提出了相应的反应机理。 石墨烯的引入可以有效地促进光生电子-空穴对的分离,从而增强光催化活性。 该复合催化剂展现出良好的活性和稳定性。 该方法以石墨烯为载体制备了光催化降解材料,为高性能光催化剂的制备提供了参考。