The InSe/g-CN van der Waals hybrid heterojunction as a photocatalyst for water splitting driven by visible light

Designing and developing the highly efficient photocatalysts is full of significance to achieve spontaneous photolysis water. In this work, using the first-principles calculations, we have performed a systematic theoretical study of water splitting photocatalytic activity of the InS e/g-CN heterojunction. It is concluded that the In Se/g-CN heterojunction is a typical type-II semiconductor, whose electrons and holes can be effectively separated. And the potential of the conduction band minimum（C...     

Highly stable water splitting on oxynitride TaON photoanode system under visible light irradiation

Highly stable photoelectrochemical water splitting is demonstrated for the first time on a tantalum oxynitride (TaON) photoanode under visible light irradiation. Highly dispersed CoO(x) nanoparticles on the TaON photoanode efficiently scavenge photogenerated holes and effectively suppress self-oxidative deactivation of the TaON surface, resulting in a stable photocurrent. The use of highly dispersed CoO(x) cocatalyst on TaON together with phosphate solutions significantly increased the photocurrent due to the formation of a cobalt/phosphate phase. This enabled us to stably split water into H(2) and O(2) under visible light irradiation at a relatively low applied bias (0.6 V vs Pt counter electrode).     

CdS的结构参数对其可见光分解水产氢性能的影响

采用水热/溶剂热法合成了球形、棒状和叶子状的CdS,并采用扫描电子显微镜(SEM)、X射线粉末衍射仪(XRD)、紫外-可见漫反射光谱(UV-vis DRS)、荧光光谱(PL)、比表面积及孔隙率分析仪(BET)等技术对其结构和光吸收特性进行了表征.考察了4种CdS光催化剂的可见光分解水产氢性能,并考察了CdS的结构参数对其活性的影响.结果表明,当Pt的负载量为1.2%(质量分数)时,L-CdS产氢速率最高,为47.77 mmol·h~(-1)·g~(-1).结构表征显示,L-CdS(002)晶面衍射峰强度特别强.(002)晶面是高指数晶面,比表面能大,这可能是其活性高的主要原因.紫外-可见漫反射光谱和荧光光谱结果也表明,L-CdS具有很好的可见光响应和较弱的荧光强度.     

磷化镍修饰磷掺杂氧化镓可见光催化水分解产氢

以Ga₂O₃半导体为前驱体,用浸渍加低温磷化法制备了P掺杂Ga₂O₃表面修饰Ni₂P光催化剂(x-Ni₂P/Ga₂O₃-P_y,x代表Ni²⁺和Ga₂O₃的物质的量之比,y代表NaH₂PO·H₂O与Ga₂O₃的物质的量之比)。5%-Ni₂P/Ga₂O₃-P₆催化剂展现出在纯水中光催化析氢的高活性,在430 nm光照下的光量子效率为0.22%。机理研究结果表明Ni₂P修饰和P掺杂扩展了催化剂的光响应范围,同时提升了载流子分离迁移效率,其长周期光催化反应稳定性明显优于未磷化催化剂。     

磷化镍修饰磷掺杂氧化镓可见光催化水分解产氢

以Ga₂O₃半导体为前驱体,用浸渍加低温磷化法制备了P掺杂Ga₂O₃表面修饰Ni₂P光催化剂(x-Ni₂P/Ga₂O₃-P_y,x代表Ni²⁺和Ga₂O₃的物质的量之比,y代表NaH₂PO·H₂O与Ga₂O₃的物质的量)。5%-Ni₂P/Ga₂O₃-P₆催化剂展现出在纯水中光催化析氢的高活性,在430 nm光照下的光量子效率为0.22%。机理研究结果表明Ni₂P修饰和P掺杂扩展了催化剂的光响应范围,同时提升了载流子分离迁移效率,其长周期光催化反应稳定性明显优于未磷化催化剂。     

吸附法制备CdS/HKLBT复合催化材料及其可见光制氢活性

采用吸附法制备了CdS和层状物的复合光催化材料CdS/HKLBT(吸附),并采用X射线衍射(XRD)、紫外-可见漫反射(DRS)、透射电子显微镜(TEM)等技术对其进行了表征和分析。实验对比了吸附法制备的复合材料与离子交换法制备材料活性差异,考察了CdS负载量对复合物制氢活性的影响.结果表明,表面复合也能明显提高CdS的可见光制氢活性,当CdS复合量为15%(质量分数)时活性最高,达到532μmol/h,与离子交换法制备的光催化剂的产氢速率接近;而过多CdS的负载造成载流子迁移的障碍,从而不利于活性的提高.     

罗丹明B敏化TiO2可见光分解水产氢研究

通过低温煅烧处理罗丹明B和P25(TiO₂)的混合物一步合成了罗丹明B敏化的TiO₂复合光催化剂。X射线衍射(XRD)和场发射扫描电子显微镜(FESEM)表征结果显示,低温煅烧处理未改变P25的晶相结构和形貌。紫外-可见光吸收光谱和红外光谱表征表明,罗丹明B和P25之间发生了强的相互作用,荧光光谱表征结果证实低温煅烧处理导致的强相互作用有利于电子从罗丹明B向P25传输。可见光光催化分解水实验结果表明,250℃下煅烧处理得到的复合光催化剂具有最佳的产氢速率,可达到65.1 μmol/(g·h),是相同光催化反应条件下罗丹明B和P25物理混合光催化剂的1.8倍。     

N-doped NaTaO_3 synthesized from a hydrothermal method for photocatalytic water splitting under visible light irradiation

NaTaO_(3-x)N_x catalysts were synthesized by a hydrothermal(H) and a solid-state(S) methods in this study.The H-and S-NaTaO_(3-x)N_x samples were characterized by X-ray diffraction(XRD), scanning electron microscopy(SEM), transmission electron microscopy(TEM), UV–visible(UV–vis) diffuse reflectance spectroscopy, and photoluminescence(PL) spectroscopy. The XRD patterns of the H-and S-samples showed peaks indexed to the pure phase of perovskite NaTaO_3 and minor peaks assignable to Ta_3N_5 at various synthesis temperatures. Substitution of oxygen by nitrogen ions causes the light absorption of the H-and S-NaTaO_(3-x)N_x samples to be extended to the 600–650 nm region, thus making the samples visible-light active. The NaTaO_(3-x)N_x samples exhibited photocatalytic activity for H_2 and O_2 evolution from aqueous methanol and silver nitrate solutions under visible-light irradiation. The UV–vis and PL spectra of the Hand S-catalysts revealed the presence of cationic vacancies and reduced metallic species, which acted as recombination centers. These results demonstrated that the preparation method plays a critical role in the formation of defect states, thereby governing the photocatalytic activity of the NaTaO_(3-x)N_x catalysts.     

First-principle investigation of TcSe2 monolayer as an efficient visible light photocatalyst for water splitting hydrogen production

Research on Chemical Intermediates - One typical two-dimensional transition metal dichalcogenide (TMDC) called the TcSe2 monolayer has been predicted to be a potential photocatalyst for water...     

Electronic structure and visible light photocatalysis water splitting property of chromium-doped SrTiO3

Cr-doped SrTi_1−xCr_xO₃ (x=0.00, 0.02, 0.05, 0.10) powders, prepared by solvothermal method, were further characterized by ultraviolet-visible (UV-vis) absorption spectroscopy. The UV-vis spectra indicate that the SrTi_1−xCr_xO₃ powders can absorb not only UV light like pure SrTiO₃ powder but also the visible-light spectrum (λ>420 nm). The results of density functional theory (DFT) calculation illuminate that the visible-light absorption bands in the SrTi_1−xCr_xO₃ catalyst are attributed to the band transition from the Cr 3d to the Cr 3d+Ti 3d hybrid orbital. The photocatalytic activities of chromium-doped SrTiO₃ both under UV and visible light are increased with the increase in the amounts of chromium.     

Reduced graphene oxide as a solid-state electron mediator in Z-scheme photocatalytic water splitting under visible light

The effectiveness of reduced graphene oxide as a solid electron mediator for water splitting in the Z-scheme photocatalysis system is demonstrated. We show that a tailor-made, photoreduced graphene oxide can shuttle photogenerated electrons from an O(2)-evolving photocatalyst (BiVO(4)) to a H(2)-evolving photocatalyst (Ru/SrTiO(3):Rh), tripling the consumption of electron-hole pairs in the water splitting reaction under visible-light irradiation.     

基于掺Zn氮化碳和BiVO4构建Z型光催化系统实现完全分解水

随着现代工业的迅猛发展和化石燃料的过量使用, 全球范围内能源和环境问题日益严峻, 因此利用丰富的太阳光能分解水来直接制取清洁的氢气具有诱人的应用前景. 目前, 聚合物半导体石墨相氮化碳(g-C3N4)因其廉价、稳定、不含金属组分和独特的电子能带结构已被广泛应用于光解水产氢研究. 然而, 氮化碳具有结晶度差、光生载流子易复合的缺点.众所周知, Z型体系可以很好地减少电子和空穴的复合问题. 同时, 催化剂只需分别满足光解水过程的一端, 这使得半导体光催化剂的选择非常丰富, 可以大大拓宽材料体系. 因此, 将g-C3N4运用到Z型体系中的研究得到了广泛关注. 然而, 这些研究多集中在如何增强g-C3N4的产氢能力方面, 对实现水的完全分解的研究鲜见报道.本实验设计了这样一种Z型体系: 使用掺Zn的g-C3N4作为产氢端, BiVO4作为产氧端, Fe3+/Fe2+作为氧化还原对. 实验结果表明, 该体系可以在全波段下实现水的完全分解(氢氧比为2:1), 并且保持相当高的稳定性.实验所使用的氮化碳为固相法烧结尿素制得, Zn的掺杂采用浸渍法, 同时通过水热法合成BiVO4, 使用Pt作为助催化剂. 通过搭建含有不同组成成分的Z型体系, 将它们的性能和表征结果进行比较分析.通过XRD, UV-Vis, SEM和XPS等测试手段对催化剂进行表征. XRD分析结果表明成功合成了掺杂Zn的石墨相氮化碳. UV-Vis则显示随着Zn浓度的提高, 吸收边发生变化. 通过改变掺杂Zn的浓度, 得到了能够实现完全分解水的Z型体系,其最佳掺杂比例为: ZnCl2和氮化碳的质量比为1:10. 为了排除单催化剂和Pt颗粒对完全分解水性能的影响, 分别作了单独产氢端、单独产氧端、预负载Pt和光沉积Pt的性能测试. 从SEM中没有发现g-C3N4和BiVO4的异质结结构. 这些结果表明所搭建的是典型的利用氧化还原离子对为中间电子传输载体的Z型体系, 经长达12 h的持续测试证明其具有较高的稳定性.为了研究Zn在构建Z型中所起的作用, 分别采用文献中报道的原位和浸渍法实现Zn的掺杂. 对这两种掺杂方式的性能测试表明, 只有采用浸渍法时, 所构建的Z型体系具有完全分解水的能力. 对这两种方法得到的掺Zn氮化碳进行表面化学组成和价态(XPS)的分析. 结果显示, 两种掺杂方法都可以通过形成Zn=N键的形式实现Zn的掺杂, 但浸渍法使Zn在g-C3N4表面分布更均匀, 同时对氮化碳原本三嗪环的破坏较小, 因此具有更好的还原能力, 可以与BiVO4匹配以构成Z型体系.实验通过采用掺杂Zn的氮化碳作为产氢催化剂, BiVO4作为产氧催化剂, Fe3+/Fe2+作为氧化还原中间体, 构建了典型的Z型体系. 该体系在Zn的掺杂浓度为10%时能够实现长时间稳定的完全分解水.     

基于分子催化剂光驱动水氧化器件的研究进展

光解水制氢是人们解决未来能源危机的一种重要构想,构建高效的光电化学池是实现这一构想的重要途径,而光驱动水氧化的顺利进行是实现这一过程的关键.本文总结了近年来基于分子催化剂及染料敏化的光驱动水氧化分子器件的研究和进展,介绍了这些分子器件的组装和性能研究等,并根据这些研究的优点和不足提出一些浅见.     

可见光驱动TaOxNy制备及其在降解二氯乙酸中的研究

近年来,国际上对于高效光催化剂的研究十分活跃[1～4].TiO2因其价廉、无毒、催化活性高等优点,受到人们的普遍重视[5～7],但TiO2光催化剂只能在紫外光区才具有催化活性,而太阳光谱中紫外光所占份额不到5%,可见光占43%.     

Photocatalytic water reduction under visible light on a novel ZnIn2S4 catalyst synthesized by hydrothermal method

A novel ZnIn2S4 catalyst synthesized by hydrothermal method shows high and stable photocatalytic activity for water reduction under visible light illumination.     

在FTO导电玻璃上电化学沉积高效可见光光电化学分解水Cu2O/g-C3N4异质结膜

近几十年来,光电化学分解水制氢作为一种洁净的、能持续利用太阳能的技术受到极大关注.在众多光催化材料中,p型半导体氧化亚铜(Cu2O)被认为是最有前途的可见光光电分解水材料之一.理论上,它的光能转换为氢能的效率可达到18.7%.然而,目前所报道的Cu2O光转换效率远远低于此值;同时,纯Cu2O在光照条件下的稳定性较差.研究表明,Cu2O与其它半导体复合可以增强其光电转换效率和提高稳定性.如Cu2O和能带匹配的石墨相氮化碳(g-C3N4)复合后,光催化性能和稳定性都有较大提高.但目前所报道的Cu2O/g-C3N4复合物几乎都是粉末状催化剂,不便于回收和重复使用.本文首先采用电化学方法在FTO导电玻璃上沉积Cu2O薄膜,采用溶胶凝胶法制备g-C3N4纳米颗粒材料,然后采用电化学法在Cu2O薄膜表面沉积一层g-C3N4纳米颗粒,得到了Cu2O/g-C3N4异质结膜.分别利用X射线粉末衍射(XRD)、高分辨透射电子显微镜(HRTEM)、扫描电子显微镜(SEM)、紫外可见光谱(UV-Vis)和光电化学分解水实验分析了Cu2O/g-C3N4异质结的组成结构、表面形貌、光吸收性能及催化剂活性和稳定性.XRD和HRTEM表征显示,本文成功合成了Cu2O/g-C3N4异质结材料,SEM图表明g-C3N4纳米颗粒在Cu2O表面分布均匀,大小均一.可见光光电化学分解水结果显示,异质结薄膜的光电化学性能比纯的Cu2O和g-C3N4薄膜材料有极大提高.当在Cu2O表面沉积g-C3N4的时间为15 s时,得到样品Cu2O/g-C3N4-15异质结膜,其在–0.4 V和可见光照射条件下,光电流密度达到了–1.38 mA/cm2,分别是纯Cu2O和g-C3N4薄膜材料的19.7和6.3倍.产氢速率也达到了0.48 mL h–1 cm–2,且产氢和产氧的速率之比约为2,说明此异质结材料在可见光作用下能全分解水.经过三次循环实验,光电化学分解水的效率仅降低10.8%,表明该材料具有良好的稳定性.根据UV-Vis表征和光电化学性能对比,Cu2O/g-C3N4-15的光电性能最好,但其光吸收性能并不是最好,说明光电化学性能与光吸收不是成正比关系,主要是由于Cu2O和g-C3N4两个半导体相互起到了协同作用.机理分析表明,Cu2O/g-C3N4异质结薄膜在光照下,由于两者能带匹配,Cu2O的光生电子从其导带转移到g-C3N4的导带上,g-C3N4价带上的空隙转移到Cu2O的价带上,从而降低了光生电子和空隙的复合,提高了其光催化性能.由于g-C3N4的导带位置高于H2O(或H+)还原为H2的电势,Cu2O的价带位置低于H2O(或OH–)还原为O2的电势,所以在外加–0.4 V偏压和可见光照射条件下,Cu2O/g-C3N4能全分解水,光生载流子越多,光电化学分解水的速率越大.综上所述,在Cu2O薄膜上沉积g-C3N4后得到的异质结薄膜具有高效的光能转换为氢能性能.     

Active and recyclable ordered mesoporous magnetic organometallic catalyst as high‐performance visible light photocatalyst for degradation of organic pollutants

A novel light‐active magnetic Pd complex as a photocatalyst was prepared through bonding organometallics to mesoporous silica channels formed on the surface of silica‐coated iron oxide nanoparticles. The nanocomposite (denoted as Fe₃O₄@SiO₂@m‐SiO₂@PDA‐Pd(0); PDA = 1,10‐phenanthroline‐2,9‐dicarbaldehyde) is more efficient and has higher photocatalytic capability in the degradation of 2,4‐dichlorophenol under visible light irradiation compared with virgin Pd complex (PDA‐Pd). This noteworthy photodegradation activity can be due to the high dispersion of Pd nanoparticles. High yield, low reaction time and non‐toxicity of the catalyst are the main merits of this protocol. Also magnetic separation is an environmentally friendly alternative method for the separation and recovery of the catalyst, since it minimizes the use of solvents and auxiliary materials, reduces operation time and minimizes catalyst loss by preventing mass loss and oxidation. The produced Pd catalyst was characterised using various techniques. Furthermore, transmission electron microscopy characterization was used for determining the structural properties of the Pd nanocatalyst.     

Photocatalytic water splitting using modified GaN:ZnO solid solution under visible light: long-time operation and regeneration of activity

Overall water splitting using GaN:ZnO solid solution photocatalyst modified with Rh(2-y)Cr(y)O(3) nanoparticles as H(2) evolution cocatalysts under visible light (400 < λ < 500 nm) was examined with respect to long-term durability and regeneration of photocatalytic activity. The rate of visible light water splitting remained unchanged for 3 months (2160 h), producing H(2) and O(2) continuously at a stoichiometric amount. After 6 months of operation, a 50% loss of the initial activity occurred. Regeneration treatment of deactivated catalysts was attempted by reloading the Rh(2-y)Cr(y)O(3) cocatalyst. The degree of activity regeneration depended on the reloading amount. Up to 80% of the initial activity for H(2) evolution could be recovered under optimal treatment conditions. It was also found that deactivation of GaN:ZnO was suppressed to some extent by prior coloading of an O(2) evolution cocatalyst, which helped to suppress oxidative decomposition of GaN:ZnO by valence band holes, thereby improving the durability.     

Unpredictable adsorption and visible light induced decolorization of nano rutile for the treatment of crystal violet

Photocatalysts containing different ratios of anatase and rutile are prepared via heat treatment of Degussa P-25 titania. X-ray diffraction (XRD), Bruuauer-Emmett-Teller (BET), ultraviolet–visible light diffuse reflectance spectra (DRS), Raman spectra (Raman), positron annihilation lifetime spectra (PAL) and temperature-programmed desorption (TPD) are applied to investigate the phase composition of the synthesized catalysts. Using crystal violet (CV) as the target pollutant, the unexpected visible light decolorization of rutile is observed. Despite the decreased specific surface area, the as-synthesized rutile samples exhibit much higher adsorption capability of CV than P-25 does, which in turn leads to improved photoreaction efficiency. Since the rutile samples can't absorb the visible light, the degradation under visible light irradiation is attributed to self-sensitization of CV on the surface of rutile.