三维球状BiOI/BiOBr异质结光催化剂制备及其光催化脱汞性能

光催化氧化技术是治理污染物排放的重要手段。目的为增强BiOBr对可见光的利用率并提高其光催化活性,方法采用共沉淀法制备碘掺杂的三维球状BiOI/BiOBr异质结光催化剂,使用X射线衍射、紫外-可见漫反射光谱、扫描电子显微镜扫描、N2吸附-脱附、X射线光电子能谱和电子自旋共振波谱等对样品结构进行表征,开展光催化脱除单质汞(Hg0)性能研究。结果结果表明,随着I含量升高,BiOBr衍射峰逐渐降低,BiOI衍射峰逐渐增强;BiOI/BiOBr复合光催化剂保留了BiOBr的三维微球形貌,BiOI均匀分散于BiOBr表面,且复合后比表面积有所提高,较大的表面积能提供更多的反应空间,促进活性自由基产生和提高光催化剂性能;与BiOBr相比,复合光催化剂的带隙能降低,可见光响应能力大幅增强。BiOI/BiOBr光催化脱汞性能高于单纯BiOI与单纯BiOBr;BiOI和BiOBr摩尔比为2∶8时,光催化剂脱汞效率高达98%,是单纯BiOBr的2.58倍;酸性条件下制备的BiOI/BiOBr异质结光催化剂会与碱性溶液反应,引起光催化剂成分的变化,进而影响光催化剂的催化性能;Hg0高效光催化氧化过程中,阴离子超氧自由基(•O_(2)^(-))和空穴(h^(+))是主要活性物质。结论研究结果可为卤氧化铋光催化剂的复合制备及其在脱汞领域的应用提供理论依据。

基于SDS临界胶束浓度调控BiOBr合成及其光催化降解头孢拉定研究

以十二烷基硫酸钠(sodium dodecyl sulfate,SDS)为模板剂,采用沉淀法制备了不同胶束浓度条件下的BiOBr光催化剂(SBr-1、SBr-2、SBr-3、SBr-4).通过XRD、SEM、BET表征BiOBr晶体结构、形貌和比表面积,结果表明在SDS为临界胶束浓度(8.0×10^(-3)mol/L)时制备的SBr-2具有较好的结晶度、特殊的形貌和最大的比表面积;运用UV-vis DRS吸收光谱、PL光谱、EIS电化学抗阻谱等表征BiOBr光电特性,结果证明SBr-2具有良好的可见光吸收能力和电子空穴分离效率.在可见光照射(λ≥420 nm)下,选用头孢拉定(cefradine,CFD)为目标污染物研究光催化活性,结果表明SBr-2具有最好的光催化活性,150 min内降解率达到98%.此外,通过自由基捕获试验,发现该光催化过程超氧自由基和空穴为主要活性物种.本研究为表面活性剂调控改善BiOBr结构、形貌和晶相提升其光催化活性提供了理论参考.

分级中空结构BiOBr-Pt催化剂用于光催化CO_(2)还原

以乙二醇为溶剂,聚乙烯吡咯烷酮为表面活性剂,通过一步溶剂热法合成了分级中空结构的BiOBr-Pt催化剂。合成的分级中空结构BiOBr-2h催化剂的比表面积为28 m^(2)·g^(-1),是对比样品BiOBr-1h的2倍,这种结构为催化反应提供更多的反应活性位点。此外,在催化剂中引入Pt增强了BiOBr的载流子传导速率,而且Pt可以作为电子陷阱捕获周围大量电子,有效抑制光生载流子的复合,从而提高CO_(2)还原的催化活性。光催化CO_(2)还原实验结果表明,BiOBr-Pt的主要产物为CO,产物选择性为99%,其CO产率达到了20.8μmol·h^(-1)·g^(-1),为原始BiOBr的2.1倍。这一结果说明,这种Pt负载且具有分级中空结构的催化剂可以有效地将CO_(2)转化为增值化学品。

Characterization and photoelectrochemical performance of Zn-doped TiO_2 films by sol-gel method

Zn-doped TiO2 (Zn?TiO2) thin films were prepared by the sol?gel method on titanium substrates with heat treatment at different temperatures. The effects of heat treatment temperatures and Zn doping on the structure, photocathodic protection and photoelectrochemical properties of TiO2 thin films were investigated. It is indicated that the photoelectrical performance of the Zn?TiO2 films is enhanced with the addition of Zn element compared with the pure-TiO2 film and the largest decline by 897 mV in the electrode potential is achieved under 300 °C heat treatment. SEM?EDS analyses show that Zn element is unevenly distributed in Zn?TiO2 films; XRD patterns reveal that the grain size of Zn?TiO2 is smaller than that of pure-TiO2; FTIR results indicate that Zn - O bond forms on Zn?TiO2 surface. Ultraviolet visible absorption spectra prove that Zn?TiO2 shifts to visible light region.Mott?Shottky curves show that the flat-band potential of Zn?TiO2 is more negative and charge carrier density is bigger than that ofpure-TiO2, implying that under the synergy of the width of the space-charge layer, carrier density and flat-band potential, Zn?TiO2 with 300 °C heat treatment displays the best photocathodic protection performance.

PMS协同Ce改性BiOBr材料光催化降解四环素

采用溶剂热合成法制备Ce(Ⅲ)改性BiOBr催化剂(Ce/Bi摩尔比0.1%~2%),通过XRD、SEM-mapping、XPS、UV-Vis等手段对其结构进行表征分析;以四环素为目标污染物,首次提出构建PMS/Ce(Ⅲ)改性BiOBr光催化体系降解四环素,考察催化剂种类、催化剂投加量、PMS摩尔浓度和p H等因素对反应体系降解四环素效果的影响。结果表明:Ce(Ⅲ)和Bi(Ⅲ)发生同晶置换,使得Ce(Ⅲ)改性BiOBr的最大吸收波长出现蓝移,提高光生电子和空穴的分离效率;PMS协同Ce(Ⅲ)改性BiOBr光催化降解四环素最佳条件:Ce与Bi的摩尔比为1%,投加量为1.0 g/L,PMS浓度为0.3 mmol/L,pH=9;四环素降解过程中,反应体系内主要活性物种为空穴,其贡献远高于硫酸根自由基和单线态氧。经重复利用实验证实,Ce改性BiOBr材料结构具有良好的稳定性。

Electrochemical Synthesis of Novel Zn-Doped TiO_2 Nanotube/ZnO Nanoflake Heterostructure with Enhanced DSSC Efficiency

The paper reports the fabrication of Zn-doped TiO_2 nanotubes(Zn-TONT)/ZnO nanoflakes heterostructure for the first time,which shows improved performance as a photoanode in dye-sensitized solar cell(DSSC).The layered structure of this novel nanoporous structure has been analyzed unambiguously by Rutherford backscattering spectroscopy,scanning electron microscopy,and X-ray diffractometer.The cell using the heterostructure as photoanode manifests an enhancement of about an order in the magnitude of the short circuit current and a seven-fold increase in efficiency,over pure TiO_2 photoanodes.Characterizations further reveal that the Zn-TONT is preferentially oriented in [001] direction and there is a Ti metal-depleted interface layer which leads to better band alignment in DSSC.

Electronic structures and optical properties of Zn-dopedβ-Ga_2O_3 with different doping sites

The electronic structures and optical properties of intrinsic β-Ga2O3 and Zn-dopedβ-Ga2O3 are investigated by first-principles calculations. The analysis about the thermal stability shows that Zn-doped β-Ga2O3 remains stable. The Zn doping does not change the basic electronic structure of β-Ga2O3, but only generates an empty energy level above the maximum of the valence band, which is shallow enough to make the Zn-doped β-Ga2O3 a typical p-type semiconductor. Because of Zn doping, absorption and reflectivity are enhanced in the near infrared region. The higher absorption and reflectivity of ZnGa（2） than those of ZnGa（1） are due to more empty energy states of ZnGa（2） than those of ZnGa（1） near Ef in the near infrared region.

Bi-MOF衍生的中空BiOBr纳米棒用于高效光催化降解环丙沙星

随着抗生素使用量的不断增加,抗生素引起的水污染日益严重,需要一种可行的解决方案来修复含有抗生素的废水.以Bi-MOF(CAU-17)为模板,制备中空BiOBr纳米棒(hBOB)用于高效光催化降解环丙沙星(CIP).与BiOBr纳米片(sBOB)相比,hBOB具有更大的比表面积和更高的电荷分离效率.在模拟太阳光下30 min的降解效率达到92.5%,降解速率常数是sBOB的2.5倍.通过固体漫反射(DRS)、荧光(PL)、光电流(I-t)、阻抗(EIS)等表征分析光降解能力增强的原因.结果表明多孔结构和纳米片组装的存在缩短了载流子的扩散距离,有利于光生载流子的分离和转移,因此hBOB具有良好的去除CIP的能力.此外,还利用莫特肖特基测试(M-S)和电子自旋共振(ESR)表征研究了光催化降解CIP的机理.

B-g-C_(3)N_(4)/BiOBr复合材料光催化降解盐酸四环素的研究

文章通过研磨和煅烧合成掺杂硼的g-C_(3)N_(4)(BCN-n),再通过溶剂热法制备硼掺杂g-C_(3)N_(4)/溴氧铋(BCN-n/BiOBr)材料,用于光催化降解盐酸四环素(TCH)污染物。文章探究了不同复合比、pH值、催化剂投加量及不同污染物浓度下BCN-n/BiOBr材料的光催化性能,并通过TEM、XRD等对材料进行表征分析。实验结果证明,BCN-2(简称BCN)∶BiOBr最佳复合质量比为2∶1。在盐酸四环素溶液浓度为20 mg/L,原液pH=5.5,催化剂投加量0.2 g/L的条件下,BCN/BiOBr(2∶1)材料对盐酸四环素的降解率达到95.1%,与相同条件下BCN和BiOBr材料相比,降解率分别提高了10.7%和14.0%。BCN/BiOBr光催化剂是一种有前景的降解TCH的光催化材料。

硅藻土/BiOBr光催化降解四环素废水研究

利用简单的溶解热法成功制备了硅藻土(DT)/BiOBr复合光催化剂,对其形貌和成分进行了表征。对复合光催化剂降解废水中四环素的性能和催化剂的稳定性进行了试验。结果表明:BiOBr纳米片在硅藻土表面分散均匀,材料纯度高、结晶性好;DT/BiOBr-1的光催化性能最好,100 min内降解四环素的效率达到95.1%,重复使用4次后依旧保持较高的催化活性。光催化降解反应中的活性物种主要是羟基自由基和光生空穴,同时超氧自由基也起到了一定的作用。

溴氧化铋(BiOBr)光催化剂的制备与改性研究进展

【目的】综述溴氧化铋(BiOBr)作为光催化剂的最新进展,深入分析其晶体结构、光催化机制、多种制备方法及高效改性策略,并探讨相关改性方法的成效。【方法】通过文献回顾和分析,详细介绍了BiOBr的晶体结构特性和光催化作用机理。对比和评估了不同的BiOBr制备技术及其优缺点。进一步讨论了各种改性手段,如离子掺杂、贵金属沉积、异质结构建、染料敏化和与新型材料的复合,并分析了这些方法提高光催化活性的途径。【结果】研究表明,通过多种制备技术可以调控BiOBr微观结构和改进光催化性能。从成本,制备难易、稳定性角度评价,最优的改性方法是贵金属沉积法。【结论】尽管BiOBr作为光催化剂已取得显著的研究进展,但仍面临诸如制备成本高、光生电子-空穴复合率高等挑战。未来的研究应着重开发更简便、稳定的BiOBr制备方法和进一步提高其光催化性能及稳定性。此外,对BiOBr光催化剂的回收和再利用也应给予足够的关注。

Ultrasonic synthesis of Zn-doped CdO nanostructures and their optoelectronic properties

The effect of Zn dopant on the growth of cadmium oxide （CdO） nanostructures through a sonochemical method wasinvestigated. The X-ray diffraction （XRD） patterns of the nanoparticles show CdO cubic structures for the produced samples. Fieldemission scanning electron microscope （FESEM） images reveal that morphologies of the samples change, when they are doped withZn atoms, and their sizes reduce. Room temperature photoluminescence （PL） and UV-Vis spectrometers were used to study opticalproperties of the samples. Evaluation of optical properties indicates that different emission bands result from different transitions andthe value of CdO energy band gap increases due to doping. Studies of electrical properties of the nanostructures demonstrate that Zndopant enhances electrical conductivity and photocurrent generation as the result of light illumination on the nanostructures due toimproved density of photo-generated carriers. Considering the obtained outcomes, Zn dopant can alter the physical property of theCdO nanostructures.

Structure and properties of Li-rich Zn-doped LiNbO_3 Crystal

The Li-rich Zn-doped LiNbO 3 (LN) crystals were grown by the Czochralski method. The structure of the crystals was measured by ultraviolet-visible absorption spectra. The results indicated that the Li-rich Zn-doped LN crystals had the same characteristics as the pure LN crystal. After Zn 2+ entered into the lattice of Li-rich Zn-doped LN crystal, it replaced Nb Li firstly. When there was no Nb Li , Zn 2+ replaced Li + then. The second harmonic generation (SHG) property of Li-rich Zn-doped LiNbO 3 crystal was measured. The results showed that the SHG conversation efficiency of Li-rich Zn-doped LiNbO 3 crystals was higher than that of Zn-doped LiNbO 3 crystals.

直接Z型MIL-100(Fe)/BiOBr异质结的构建及光芬顿降解磺胺甲恶唑的性能

通过原位共沉淀法可控制备了系列直接Z型MIL-100(Fe)/Bi OBr异质结。使用粉末X射线衍射(PXRD)、傅里叶红外变换(FTIR)光谱、紫外可见漫反射光谱(UV-Vis DRS)、扫描电镜(SEM)、高倍透射电镜(HRTEM)以及X射线光电子能谱(XPS)对MIL-100(Fe)/Bi OBr异质结晶体结构、微观形貌、光学性能、化学组成进行表征。以低功率发光二级管可见光为光源,探究了MIL-100(Fe)/Bi OBr异质结光芬顿降解磺胺甲恶唑(SMX)性能。最佳反应体系MB-7/Vis/H_(2)O_(2)(MB-7是MIL-100(Fe)质量为Bi OBr质量的70%时制备的样品)在光源照射70 min后可降解99.8%SMX(5 mg·L^(-1))。同时,还考察了H_(2)O_(2)浓度、催化剂投加量、p H值以及无机阴离子对MB-7/Vis/H_(2)O_(2)降解SMX影响。MB-7/Vis/H_(2)O_(2)能够在经过5轮循环降解实验后保持95%以上的SMX降解效率,表明其具有较好的循环稳定性。通过光致发光(PL)光谱、光电化学测试、活性物质捕获实验以及电子自旋共振(ESR)技术对光芬顿降解SMX机理进行了揭示。增强的光芬顿活性的机制主要来自于异质结的构建加速了光生载流子的分离,进而促进了活性物质产生以及Fe^(3+)/Fe^(2+)的循环。

BiOBr/CdS异质结构材料的制备及其光催化还原Cr6+的研究

全球经济的蓬勃发展给人类社会带来了物质方面的极大满足,与此同时也导致了环境污染和能源短缺等问题的出现。目前来说,光催化技术是一种环境友好型处理环境污染的方式,BiOBr材料具有独特的层状结构及合适的带隙,这使得其具有独特的光催化性能。本实验以乙二醇为溶剂,以五水硝酸铋和十六烷基三甲基溴化铵为原料,通过溶剂热法合成了花形BiOBr,并以其为基底,通过一锅水浴法制得了BiOBr/CdS复合催化剂。为了评价其降解废水污染物(本实验以重铬酸钾作为模拟污染物)的作用,将BiOBr及BiOBr/CdS作为模型光催化剂,通过XRD、SEM、DRS、PL、EIS等一系列表征对其进行了深入的研究。光催化实验结果显示:在可见光的环境下,复合光催化剂BiOBr/CdS在进行光催化反应21 min后,对Cr(VI)的还原效率高达96.42%,远高于单一BiOBr催化剂的还原效率,是单一BiOBr催化剂的1.38倍。

CeO_(2)/BiOBr/CNTs催化剂的制备及其降解抗生素性能研究

采用水热法合成了CeO_(2)、CeO_(2)/BiOBr、CeO_(2)/CNTs和CeO_(2)/BiOBr/CNTs复合纳米材料催化剂,利用XRD、SEM、BET和UV-Vis等方法对材料的结构、形貌和织构特性进行表征。在长弧氙灯照射下模拟太阳可见光降解抗生素,研究复合纳米材料的光催化氧化性能。结果表明,CeO_(2)与BiOBr、CNTs间的协同作用导致其对土霉素降解效果优于CeO_(2);CeO_(2)/BiOBr/CNTs对抗生素和可见光具有更高的吸收性能,比CeO_(2)/BiOBr和CeO_(2)/CNTs有更高的降解效率。在弱碱性环境下生成活性基团·OH,复合材料催化效果较好。复合材料禁带宽度都在可见光范围内,CeO_(2)的复合提高了材料的光利用效率,增强了材料的吸附性和电子-空穴对的迁移效率,进而提高其光催化活性。回收脱附实验表明,CeO_(2)/BiOBr/CNTs复合材料具有较好的稳定性。

BiOBr nanosheets coupling with biomass carbon derived from locust leaves for enhanced photocatalytic degradation of rhodamine B

A series of BiOBr@biomass carbon derived from locust leaves materials(BiOBr@BC)were fabricated and the photocatalytic property was investigated for photocatalytic degradation of rhodamine B(RhB)under visible light.The morphology,structure and photoelectrochemical properties of the photocatalysts were characterized by means of SEM,TEM,XRD,XPS,FT-IR,BET,PL,UV-vis/DRS,and EIS techniques.The results showed that the introduction of BC significantly enhanced the photocatalytic activity.When the content of biomass carbon(BC)in a composite is 3%(based on the mass of BiOBr),the obtained BiOBr@BC-3 exhibits excellent photocatalytic activity,degrading 99%of RhB within 20 min.The excellent degradation efficiency after the introduction of BC can be attributed to the enhanced visible light absorption,narrower band gap,and fast electron-hole pair separation rate.The photocatalytic mechanism on the degradation of RhB was illustrated based on the radicals'trapping experiments and semiconductor energy band position.The proposed material is expected to be of significant application value in the field of wastewater treatment.

花状微球BiOBr光催化剂的制备及光催化活性研究

采用溶剂热法,以Bi(NO3)3·5H2O和十六烷基三甲基溴化铵(CTAB)为原料,乙二醇为溶液,制备花状微球的BiOBr。运用XRD、SEM、EDX和UV-Vis等手段对其进行表征。以可见光下降解罗丹明B为研究对象,考察了催化剂投加量、染料溶液初始浓度等对光催化活性的影响,并对催化剂的稳定性进行了研究。结果表明,BiOBr有着出色的稳定性,在可见光下展现出较高的催化活性,当投加量为0.2g,可见光下照射30min,20mg/L的罗丹明B溶液能全部降解。

g-C3N4-BiOBr复合材料制备及可见光催化性能

利用原位沉积法将Bi OBr纳米片生长到g-C_3N_4表面,制得g-C_3N_4-Bi OBr p-n型异质结复合光催化剂。采用X射线衍射(XRD)、红外光谱(FTIR)、场发射扫描电子显微镜(FE-SEM)、透射电子显微镜(TEM)、紫外可见漫反射(UV-Vis-DRS)和荧光光谱(PL)等测试对光催化剂结构和性能进行表征。通过可见光辐照降解甲基橙水溶液检测评估复合光催化剂光催化活性。研究结果表明:复合光催化剂由Bi OBr和g-C_3N_4两相组成,Bi OBr纳米片在片状g-C_3N_4表面快速形核生长形成面-面复合结构。相比于纯相g-C_3N_4和Bi OBr,g-C_3N_4-Bi OBr复合材料具有更强可见光吸收能力,吸收带边红移。在可见光辐照100 min后,性能最佳的2:8 gC_3N_4-Bi OBr复合光催化剂光催化活性分别是纯相g-C_3N_4和Bi OBr的1.8和1.2倍,经过4次循环实验后,其降解率仍达84%,说明复合结构光催化剂催化性能和稳定性增强。复合光催化剂的荧光强度显著降低,说明光生载流子复合得到了有效抑制。复合光催化剂催化性能的提高归因于p-n型异质结促进电荷有效分离、抑制电子-空穴复合和吸收光波长范围的扩展,相比单一成分材料具有更好的催化活性和稳定性。自由基捕获实验证明,可见光降解甲基橙光催化过程中的主要活性成分为空穴,并据此提出了可能的光催化机理。

类微乳化学沉淀法合成BiOBr-TiO_2纳米复合材料及其光催化性能

采用简单的类微乳化学沉淀法获得了有效复合的BiOBr-TiO2纳米材料.该合成方法的关键在于Br-的双重作用.Br-既作为"桥"将十六烷基三甲基溴化铵(CTAB)中CTA+与TiO2粒子相连,构筑了稳定的油包水的类微乳体系.同时,它又作为BiOBr的溴源有助于纳米复合材料异质结的形成.与纯TiO2和传统的水相化学沉淀法获得的BiOBr-TiO2复合样品相比,采用类微乳化学沉淀法获得的复合光催化剂表现出高的光生电荷分离效率,相应地显示出优异的光催化降解气相乙醛和液相苯酚的性能,这主要与BiOBr和TiO2粒子之间异质结的有效构筑有关.