反应溶剂对Bi2S3粉体形貌的影响

利用溶剂热法在不同反应溶剂中制备了不同尺寸的Bi2S3纳米管和纳米棒.利用XRD、SEM、TEM、选区电子衍射(SAED)和高分辨透射电镜(HRTEM)对其结构和形貌进行了表征.结果表明,所制备的产物是结晶良好的正交相Bi2S3,反应溶剂的表面张力、粘度大小和反应溶剂中的比例影响纳米粉体的形貌和尺寸.紫外-可见光吸收光谱测量表明,由于尺寸效应所有粉体的吸收谱相对于正交相的Bi2S3块体都出现蓝移.     

水热环境下磁场对BiFeO_3形貌和性能的影响

以Bi(NO_3)_3·5H_2O和Fe(NO_3)_3·9H_2O为反应原料,KOH为矿化剂,通过在碱浓度为2~7 mol/L、反应温度为140~220℃的磁场水热反应系统中保温1~12 h制备了Bi Fe O_3粉体.研究发现,外加磁场可以拓宽合成纯相Bi Fe O_3的碱浓度和反应温度范围,更易得到纯相铁酸铋粉体.SEM观测结果表明,通过改变磁场强度可有效控制Bi Fe O_3粉体的颗粒尺寸及形貌:随着磁场的增强,Bi Fe O_3的颗粒尺寸逐渐减小.随着颗粒尺寸的减小,其光催化活性增强.磁场下得到的粉体表现出较强的磁性,Raman散射中A_1-2振动模式异常增强.     

水热法合成Bi2S3纳米管及其生长机理

以硝酸铋[Bi(NO)3]和硫化钠(Na2S)为反应原料, 采用水热法在120 ℃下反应12 h, 制备出Bi2S3纳米管. 利用X射线粉末衍射(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)、选区电子衍射(SAED)和高分辨透射电镜(HRTEM)对其结构和形貌进行了表征. 结果表明, 所制备的产物是结晶良好的正交相Bi2S3纳米管, 其外径为100~500 nm, 内径为50~200 nm, 长为1~5 μm. 根据实验结果讨论了Bi2S3纳米管的生长机理. 初步研究了反应温度和矿化剂种类对产物形貌和结构的影响.     

Bi–O–Si键作为热电子传输通道增强SiO2@Bi微球的等离子体光催化效率

具有等离子体效应的贵金属Au和Ag等常被用于修饰半导体光催化剂.非贵金属Bi成本低,来源丰富,最近被报道可以直接作为等离子体光催化剂应用于空气中NO净化.为了进一步提高Bi单质的光催化活性,需对其进行改性.SiO2的禁带宽度过大,不能单独作为光催化剂,但它的稳定性好,比表面积大,因而常作复合材料用于提高光催化剂的反应效率、稳定性及对反应物的吸附能力.目前,尚未见SiO2修饰Bi单质的相关报道.本文通过溶剂热法制备了SiO2@Bi微球,并对其微结构进行了表征,对光催化氧化NO的反应过程进行了原位漫反射红外光谱(DRIFTS)分析,揭示了Bi–O–Si键在提升SiO2@Bi光催化氧化NO性能中的作用机制.结果显示,用SiO2纳米颗粒修饰Bi球,形成的Bi–O–Si键作为热电子传输通道,能显著提高Bi单质光催化氧化去除NO的能力.扫描电镜、透射电镜、傅里叶变换红外光谱和X射线光电子能谱等表征结果表明,SiO2纳米颗粒负载于Bi球上,且SiO2@Bi内形成了Bi–O–Si键.作为光生热电子的传输通道,Bi–O–Si键能促进光生电子的转移和载流子的分离,提高活性自由基?OH和?O2?的产量,增强SiO2@Bi在紫外光下等离子体光催化氧化NO的能力.自由基捕获测试(ESR)表明,SiO2@Bi在光催化反应中产生的?OH和?O2?数量均明显高于单质Bi在反应中形成自由基的数量.原位DRIFTS发现,Bi–O–Si键能快速转移光生电子,从而有利于NO→NO2→NO3?反应的进行.此外,SiO2@Bi的比表面积变大,因而对NO的吸附能力增强,同时促进了光催化反应.本文揭示了SiO2@Bi等离子体光催化性能增强的微观机制和光催化氧化NO的反应机理,为Bi基光催化剂的改性和应用提供了新的认识.     

电沉积Bi2Te3基薄膜的电化学阻抗谱研究

以不锈钢为基底,利用电化学沉积方法制备Bi2Te3基薄膜材料,并采用X射线衍射技术、电子探针微观分析等方法对薄膜进行结构和成分表征,通过电化学阻抗谱技术对不锈钢表面Bi2Te3的电化学沉积机理进行了初步探讨.结果表明Bi-Te和Bi-Te-Se体系具有相似的电化学沉积机理,即Bi3+和2HTeO+或H2SeO3首先被还原为Bi单质和Te或Se单质,然后Bi单质与Te或Se单质反应生成Bi2Te3基化合物,而Bi-Sb-Te体系中,2HTeO+首先被还原为Te单质,生成的Te再与Bi3+和Sb(III)反应生成Bi2Te3基化合物,三种体系的沉积都受电化学极化控制.     

三溴偶氮溴膦（4—BPA—TB）与铋显色反应研究及分析上应用

本文报道了三溴偶氮溴膦(4-BPA-TB)与Bi(Ⅲ)的显色反应.研究结果表明:在高氯酸介质中,乙醇存在下,该试剂与Bi(Ⅲ)形成稳定的蓝紫色配合物,配合比为1:2,其最大吸收波长为644nm,表观摩尔吸光系数为1.0×10~5,Bi(Ⅲ)0～20μg/25ml范围内符合比耳定律.将该方法用于铸铁及紫铜样品中微量铋的测定,获得了满意的结果.     

Bi–O–Si键作为热电子传输通道增强SiO_2@Bi微球的等离子体光催化效率（英文）

具有等离子体效应的贵金属Au和Ag等常被用于修饰半导体光催化剂.非贵金属Bi成本低,来源丰富,最近被报道可以直接作为等离子体光催化剂应用于空气中NO净化.为了进一步提高Bi单质的光催化活性,需对其进行改性.SiO_2的禁带宽度过大,不能单独作为光催化剂,但它的稳定性好,比表面积大,因而常作复合材料用于提高光催化剂的反应效率、稳定性及对反应物的吸附能力.目前,尚未见SiO_2修饰Bi单质的相关报道.本文通过溶剂热法制备了SiO_2@Bi微球,并对其微结构进行了表征,对光催化氧化NO的反应过程进行了原位漫反射红外光谱(DRIFTS)分析,揭示了Bi–O–Si键在提升SiO_2@Bi光催化氧化NO性能中的作用机制.结果显示,用SiO_2纳米颗粒修饰Bi球,形成的Bi–O–Si键作为热电子传输通道,能显著提高Bi单质光催化氧化去除NO的能力.扫描电镜、透射电镜、傅里叶变换红外光谱和X射线光电子能谱等表征结果表明,SiO_2纳米颗粒负载于Bi球上,且SiO_2@Bi内形成了Bi–O–Si键.作为光生热电子的传输通道,Bi–O–Si键能促进光生电子的转移和载流子的分离,提高活性自由基·OH和·O_2~-的产量,增强SiO_2@Bi在紫外光下等离子体光催化氧化NO的能力.自由基捕获测试(ESR)表明,SiO_2@Bi在光催化反应中产生的·OH和·O_2~-数量均明显高于单质Bi在反应中形成自由基的数量.原位DRIFTS发现,Bi–O–Si键能快速转移光生电子,从而有利于NO→NO_2→NO_3~-反应的进行.此外,SiO_2@Bi的比表面积变大,因而对NO的吸附能力增强,同时促进了光催化反应.本文揭示了SiO_2@Bi等离子体光催化性能增强的微观机制和光催化氧化NO的反应机理,为Bi基光催化剂的改性和应用提供了新的认识.     

阻抑动力学光度法测定水样中的痕量铋

基于弱酸介质中, 在十二烷基磺酸钠(SDS)存在下, 痕量Bi3 对H2O2氧化结晶紫(CV)的褪色反应有明显的阻抑作用, 建立了测定痕量Bi3 的阻抑动力学光度法, 研究了该反应的最佳实验条件和动力学参数. 结果表明, 该方法检出限为2.77×10-8 g/L, 线性范围为0～0.008 μg/mL. 可用于环境水样中铋的测定.     

Bi/BiOI/(BiO)2CO3异质结可见光催化净化NO的性能增强

窄带隙Bi OI光催化剂因电荷重组速率快而导致其可见光下的光催化效率较低.本文以NaBH4为还原剂,采用简单的常温原位组装法在Bi OI上构建氧空位、金属Bi颗粒和Bi_2O_2CO_3共作用,以克服Bi OI的缺点.在合成的三元Bi/BiOI/(BiO)_2CO_3中,氧空位、双异质结(即Bi/BiOI和Bi OI/(BiO)_2CO_3)以及Bi粒子的表面等离子体共振效应均促进了电子-空穴分离和电荷载流子浓度的增加,从而提高了可见光的整体光催化效率.将制备的催化剂用于可见光下去除连续流空气中的ppb级NO.结果表明, Bi/BiOI/(BiO)_2CO_3的NO去除率显著增强,大约为50.7%,并远高于BiOI(1.2%).密度泛函理论计算和实验结果表明, Bi/BiOI/(BiO)_2CO_3复合材料可明显促进光催化NO氧化的活性氧生成.本文可提供一个新的策略来改性窄带隙半导体和探索其他含铋异质结构的可见光驱动光催化剂.XRD结果发现, BOI-70中出现Bi和(BiO)_2CO_3的特征峰,但BOI却很微弱; XPS结果表明,高价态Bi~(3+)被NaBH4部分还原而形成低价态金属Bi颗粒,且I3d峰位结合能进一步证实了BOI-70样品中存在BiOI,由此可见,成功制备了三元Bi/BiOI/(BiO)_2CO_3异质结催化剂, EPR结果表明氧空位的产生.SEM和TEM结果表明, Bi OI和三元Bi/BiOI/(BiO)_2CO_3催化剂为纳米片组装的花状结构.HRTEM的结果进一步显示了金属铋、正方晶相Bi OI和(BiO)_2CO_3对应的晶格间距.紫外-可见光催化去除NO的测试结果表明, BOI-70(50.7%)的光催化活性明显高于BOI(1.2%)和P25(11.5%),且在循环测试实验中表现出优异的稳定性.UV-visDRS测试结果显示, BOI-70具有更强的光吸收;PL结果表明,其光生电子-空穴对的分离效率更高.ESR结果表明,参与反应的主要活性物种为·O2-和·OH自由基.DFT计算结果证实了OVs对电荷载流子的局部环境和快速传输:OV为电子捕获陷阱,使电子从OVs转移到O_2分子形成活性氧物种;O2表面的吸附能从无缺陷BiOI时的–0.29 e V降到有缺陷的–0.76 eV, O-O键长从1.30增至1.37?,说明OVs通过降低氧的吸附能可促进O2分子在光催化剂表面的吸附.综上所述,由于BiNPs的异质结效应和SPR效应以及OVs的存在, Bi/BiOI/(BiO)_2CO_3三元体系的原位组装通过增加载流子浓度和加速电子空穴分离使光催化活性显著增加.     

氮掺杂Bi2O3光催化剂可见光催化降解2,4-二氯酚

采用自制的Bi2O3及氮掺杂Bi2O3(N-Bi2O3)光催化剂,以卤钨灯为光源,在可见光下对2,4-二氯酚进行光催化降解.结果表明,N-Bi2O3较Bi2O3具有更高的可见光催化活性.当N-Bi2O3光催化剂投加量为2.0 g/L、2,4-二氯酚初始浓度为20 mg/L和pH =7时,光催化反应320 min,2,4-二氯酚的降解率最高可达到91.5％.2,4-二氯酚的光催化反应初活性与其浓度之间的关系符合Langmuir-Hinshelwood动力学速率模型.对降解过程中总有机碳及Cl-测试结果表明,N-Bi2O3光催化剂能较好地完成对2,4-二氯酚的深度矿化及脱氯.     

Speciation of Mercury in Terrestrial Plants Using Vapor Generation and Liquid Chromatography–Inductively Coupled Plasma Mass Spectrometry

A sensitive method for mercury speciation in biological samples is reported. A simple vapor generation apparatus was coupled to liquid chromatography and inductively coupled plasma–mass spectrometry (ICP–MS) to achieve a substantial increase in sensitivity. Mercury(II) and methylmercury were separated by reversed-phase chromatography as thiolate compounds with 2-mercaptoethanol. A short reverse phase column with an octylated stationary phase (75 × 4 millimeters) was used with a mobile phase containing 0.02 mole per liter ammonium acetate, 0.2 percent (v/v) 2-mercaptoethanol, and 1 percent methanol. The effluent was mixed with hydrochloric acid (0.06 mole per liter) containing platinum (40 micrograms per liter) as the internal standard and bismuth (30 micrograms per liter) as a modifying agent followed by sodium borohydride (0.016 mole per liter). The generated volatile species were introduced into the ICP–MS by conventional solution nebulization. In addition to the sensitivity enhancement induced by vapor generation, the addition of bismuth further increased the methylmercury signal with a reduced increase in the mercury(II) signal. As a result, comparable but unequal signals were achieved: the mercury(II) signal was approximately 1.6-fold higher than the methylmercury signal. Extraction with a hydrochloric acid-2-mercaptoethanol solution was used for sample preparation. The accuracy of determination was verified using two standard reference materials and an interlaboratory reference material based on barley grown hydroponically in mercury-contaminated solution. The method was employed for mercury speciation of plant samples from a polluted region.     

锡掺杂Bi2O3可见光响应光催化剂的制备及性能

以硝酸铋和四氯化锡为原料,采用浸渍法制备了纯Bi2O3和Sn掺杂Bi2O3光催化剂。利用X射线光电子能谱、X射线荧光光谱、X射线衍射、扫描电子显微镜、紫外-可见吸收光谱和光致发光光谱对样品进行了表征。在可见光下,利用2,4-二氯苯酚水溶液的光催化降解作为探针反应,考察了样品的可见光催化活性。结果表明,浸渍法能较好地实现Sn的掺杂,催化剂中掺杂剂Sn的价态为+4价,以锡的氧化物形式存在于Bi2O3晶格间隙或晶粒表面。并且掺杂适量的Sn,可有效抑制Bi2O3晶相由四方相向单斜相的转变,拓宽了Bi2O3的可见光响应范围,有效阻止了光生电子和空穴的复合,从而提高了Bi2O3的可见光催化活性。当Sn的掺杂量为2%时(物质的量的分数),Bi2O3具有最好的可见光催化活性。     

Investigation of Copper(II) Interference on the Anodic Stripping Voltammetry of Lead(II) and Cadmium(II) at Bismuth Film Electrode

The bismuth‐coated electrode is known to be prone to errors caused by copper(II). This study investigates copper(II) interference at bismuth film electrode for the detection of lead(II) and cadmium(II). It was conducted using glassy carbon electrode, while the bismuth film was plated in situ simultaneously with the target metal ions at ? 1200 mV. Copper(II) presented in solution significantly reduced the sensitivity of the electrode, for example there was an approximately 70 % and 90 % decrease in peak signals for lead(II) and cadmium(II), respectively, at a 10‐fold molar excess of copper(II). The decrease in sensitivity was ascribed to the competition between copper and bismuth or the metal ions for surface active sites. Scanning electron microscopy (SEM) and energy dispersive X‐ray (EDX) analysis suggested a large decrease in the amount of bismuth nanoparticles formed on the electrode surface in the presence of copper(II) occurred, validating the competition between copper and bismuth ions for surface active sites. Recovery of the stripping signal of lead(II) and cadmium(II) was obtained by adding ferrocyanide ion to the solution. Finally, the proposed method was successfully applied to determine lead(II) and cadmium(II) in water samples and the method was validated by ICP‐MS technique.     

Generation of a methylbismuth species and its electrothermal vaporization for the determination of bismuth by inductively coupled plasma mass spectrometry

Inorganic bismuth(III) was converted to a methylbismuth species, possibly trimethylbismuth, by a thermochemical reaction with methyllithium. It instantly vaporized and was then introduced into the ICP ion source to detect the 209Bi signal. Utilizing an exchangeable small sample cuvette placed on the tungsten boat furnace for the reaction was very favorable from the viewpoints of easy handling, no memory effect, and maintenance of furnace conditions. In this manner, the analyte was vaporized at quite a low temperature (150 degrees C). The detection limit (3sigma) was 0.13 pg of bismuth and the precision in relative standard deviation for 5.0 pg of bismuth was determined to be 3.8% (n = 7).     

钛酸铋系化合物的光催化性能研究

采用化学溶液分解法制备了钛酸铋化合物: Bi₁₂TiO₂₀, Bi₄Ti₃O₁₂和Bi₂Ti₂O₇, 并采用XRD表征了其结构. 用TEM观察发现其平均粒径＞100 nm, UV-Vis漫反射谱测定显示它们在可见光区均呈现极强的吸收特征. 紫外光照射下甲基橙的光催化降解脱色实验表明, 三种钛酸铋化合物均具有较强的光催化活性, 其中, Bi₁₂TiO₂₀的光催化活性最强, 几乎与P-25相同. 钛酸铋化合物光催化性能的不同在于它们具有不同的晶相结构和电子结构.     

Bi2O3 /TiO2复合纳米颗粒的可见光光催化性能

采用溶胶与水热相结合的方法合成了具有可见光光催化活性的复合纳米颗粒Bi2O3/TiO2,并对其进行了X射线衍射、透射电镜、X射线光电子能谱、紫外-可见漫反射谱、红外光谱、低温N2吸附脱附及电子顺磁共振分析。结果表明,复合少量的氧化铋可显著抑制TiO2由锐钛矿到金红石的相转移过程,并将光吸收范围扩展到可见光区。可见光照射下(λ>420 nm),利用电子顺磁共振技术检测到明显的羟基自由基(.OH)信号。铋的最佳掺杂量为Bi/Ti质量比2.0%,适量铋的掺入能显著改善锐钛矿TiO2的结晶度,抑制光生电子-空穴对的复合,提高光催化量子效率。通过可见光照射下,4-氯酚的降解实验测试Bi2O3/TiO2复合纳米颗粒的可见光光催化活性。同时,利用气-质联用仪对4-氯酚降解过程的中间产物进行了测定,并提出可见光照射下的Bi2O3光敏化机理。     

Synthesis of cross-linked chitosan modified with the glycine moiety for the collection/concentration of bismuth in aquatic samples for ICP-MS determination.

A chelating resin, cross-linked chitosan modified with the glycine moiety (glycine-type chitosan resin), was developed for the collection and concentration of bismuth in aquatic samples for ICP-MS measurements. The adsorption behavior of bismuth and 55 elements on glycine-type chitosan resin was systematically examined by passing a sample solution containing 56 elements through a mini-column packed with the resin (wet volume; 1 ml). After eluting the elements adsorbed on the resin with nitric acid, the eluates were measured by ICP-MS. The glycine-type chitosan resin could adsorb several cations by a chelating mechanism and several oxoanions by an anion-exchange mechanism. Especially, the resin could adsorb almost 100% Bi(III) over a wide pH region from pH 2 to 6. Bismuth could be strongly adsorbed at pH 3, and eluted quantitatively with 10 ml of 3 M nitric acid. A column pretreatment method with the glycine-type chitosan resin was used prior to removal of high concentrations of matrices in a seawater sample and the preconcentration of trace bismuth in river water samples for ICP-MS measurements. The column pretreatment method was also applied to the determination of bismuth in real samples by ICP-MS. The LOD of bismuth was 0.1 pg ml(-1) by 10-fold column preconcentration for ICP-MS measurements. The analytical results for bismuth in sea and river water samples by ICP-MS were 22.9 +/- 0.5 pg ml(-1) (RSD, 2.2%) and 2.08 +/- 0.05 pg ml(-1) (RSD, 2.4%), respectively.     

Generation of a methylbismuth species and its electrothermal vaporization for the determination of bismuth by inductively coupled plasma mass spectrometry

Inorganic bismuth(III) was converted to a methylbismuth species, possibly trimethylbismuth, by a thermochemical reaction with methyllithium. It instantly vaporized and was then introduced into the ICP ion source to detect the ²⁰⁹Bi signal. Utilizing an exchangeable small sample cuvette placed on the tungsten boat furnace for the reaction was very favorable from the viewpoints of easy handling, no memory effect, and maintenance of furnace conditions. In this manner, the analyte was vaporized at quite a low temperature (150 °C). The detection limit (3σ) was 0.13 pg of bismuth and the precision in relative standard deviation for 5.0 pg of bismuth was determined to be 3.8% (n = 7). Received: 6 June 1999 / Revised: 31 August 1999 / /Accepted: 23 September 1999     

Determination of zinc in high purity bismuth by thermal neutron activation

A neutron activation analysis for the determination of zinc in bismuth was developed. After irradiating the samples for 44 days at 4·10¹¹n/cm²/sec, zinc was separated quantitatively by hexone extraction and precipitation as quinaldate. The sensitivity of the method was estimated as 0.05 p.p.m. No zinc could be detected in the high purity bismuth samples. An addition method of analysis showed that the precision was 1.2%.     

Obtaining Metallic Bismuth in Condensed Media Composed of Formates

Microcrystalline metallic bismuth powders of varied morphology were obtained by reduction of bismuth precursors, basic bismuth formate and bismuth(III) formate in benzyl alcohol, hydrazine hydrate, and sodium borohydride. The methods of X-ray diffraction analysis, scanning electron microscopy, thermogravimetry, and differential scanning calorimetry were used to examine the phase composition and the morphology of the resulting metallic bismuth powders. A dispersion analysis of bismuth samples was made by the method of small-angle scattering of light for a proximate monitoring of the particle size in powders of different fractions. The specific surface area of the metallic bismuth sample was determined by the thermal desorption of argon.