液体硅肥中砷形态的氢化物发生原子荧光光谱分析

本文应用氢化物发生-原子荧光光谱法(HG-AFS)测定了液体硅肥中不同形态的砷含量。研究了酸介质、还原剂和增感剂对砷的荧光信号的影响。实验确定酸介质为2.5 mol.L-1HCl,还原剂和增感剂为5%硫脲 5%抗坏血酸混合溶液。在选定的实验条件下测得硅肥中三价砷、五价砷及总砷的含量分别为5.08 ng.L-1、0.72 ng.L-1、5.80 ng.L-1。三价砷和五价砷的检出限分别为72.0 ng.L-1和153 ng.L-1;方法的精密度为2.2%~4.1%,回收率为96.5%~104%。     

高效液相色谱-氢化物发生-原子荧光光谱在线联用系统分析中成药中砷化合物形态

建立了高效液相色谱-氢化物发生-原子荧光光谱砷形态分析在线联用系统,考察了不同实验条件对4种砷形态化合物（As^Ⅲ,DMA^Ⅴ,MMA^Ⅴ和As^Ⅴ）分离分析的影响,优化了实验条件.在优化的实验条件下,采用pH 5.8的磷酸盐缓冲溶液为流动相,梯度洗脱,10 min之内4种砷形态达到基线分离.进样20μL,测定4种形态的检出限分别为：As^Ⅲ2.76 ng/mL,DMA^Ⅴ7.37 ng/mL,MMA^Ⅴ2.86 ng/mL和As^Ⅴ5.22 ng/mL,相对标准偏差RSD在2.9%～4.2%之间.该联用系统灵敏度高,准确性好,分离分析了部分市售中成药中的不同砷形态化合物.     

蜈蚣草孢子囊元素组成的X射线光谱分析

砷超富集植物蜈蚣草具有超强的砷吸收和富集能力,生物量大,被认为是修复砷污染土壤的理想植物材料.基于砷超富集植物蜈蚣草的植物修复技术已经推广应用到了我国20多个污染区的土壤修复实践中.目前所报道的所有蜈蚣草均具有砷超富集能力,并且该特性能够得到稳定遗传.蜈蚣草是如何通过仅仅几十个微米的孢子将这种砷超富集能力传递给下一代?...     

石墨炉原子吸收光谱法测定生活饮用水中砷的方法优化

建立了石墨炉原子吸收光谱(GFAAS)法测定生活饮用水中砷的方法。升压放电空心阴极灯的使用,降低了基线噪声水平和检出限。对温度程序、化学基体改进剂和热稳定剂进行了优化并用于GFAAS测定砷,无需进行初步处理。研究结果显示,线性方程为y=0.005 62x+0.000 04,相关系数R为0.998 3,样品体积为16μL时的检出限为0.26μg/L。加标回收率为98.1%～99.2%,相对标准偏差<5%。取实际饮用水样验证了其适用性。     

硝酸-过氧化氢敞口消解/ICP-MS测定植物样品砷含量

选取了玉米秸秆与籽粒、小麦秸秆与籽粒、烟草等5种不同的植物样品,加入硝酸-过氧化氢,进行敞口消解,消解液中As(⁷⁵As)采用电感耦合等离子体质谱仪He碰撞模式测定,以⁷²Ge为内标元素。结果表明：2个国家生物成分分析标准物质GBW10011(GSB-2,小麦)和GBW10020(GSB-11,柑橘叶)砷的测定值在标准确认值范围内;在植物样品中加入砷标准溶液,加标回收率在87%~104%之间;方法检出限为0.0055 μg/g,灵敏度较高;对4个植物样品分别重复测定5次,相对标准偏差均小于10%。本文结论认为电感耦合等离子体质谱仪He碰撞模式可以用于测定硝酸-过氧化氢敞口消解植物样品中砷含量,该方法测定结果准确可靠,重现性好,灵敏度高。     

Zur oxidativen Addition von komplexierten Phosphanen bzw. Arsanen an Platin(0)‐Komplexen

Oxidative Addition Reactions of Complexed Phosphine and Arsine at Platinum(0) Complexes The reactions of E(SiMe₃)₃ with [W(CO)₅thf] yield after alcoholysis in a one‐pot reaction the complexes [(CO)₅WEH₃] ( 1 ) (E = P( a ), As( b )). This procedure circumvents the direct use of gaseous phosphine and arsine, respectively. Complexes 1 react with [(C₂H₄)Pt(PPh₃)₂] in an oxidative addition type reaction to form the heterometallic complexes [(PPh₃)₂Pt(H){(μ‐EH₂)W(CO)₅}] (E = P( 2 ), As( 3 )). Complexes 2 and 3 were obtained as mixtures of their cis‐ and trans‐isomers, in which the contents of the trans‐isomer dominates. The products were comprehensively spectroscopically characterised, and the structures of the trans‐complexes 2 and 3 were determined by X‐ray crystal structure analysis.     

Stiba-, Arsa- and Phosphastannenes: Syntheses and Reactivities

A facile synthesis for unprecedented stibastannene ( 10 ) featuring a Sn=Sb-double bond together with the homologous arsa- ( 9 ) and phosphastannenes ( 8 ) is presented. Chloride abstraction from respective stannyl pnictinidenes [E=P ( 5 ), As ( 6 ), Sb ( 7 )], which were made accessible by reduction of ECl₃ addition products at an intramolecular phosphine-stabilized stannylene, gave the pnictastannenes in moderate yields. The pnictastannenes coordinate Pd(PPh₃)₂ fragments ( 12 – 14 ) and the phosphastannene forms also a nickel coordination compound with the Ni(PPh₃)₂-fragment ( 11 ). 2,3-Dimethylbutadiene shows a [2+4]-cycloaddition ( 15 – 17 ) in reaction with the pnictastannenes ( 8 – 10 ). Products of a [2+2]-addition ( 18 , 19 ) were isolated as the phosphaalkyne reaction products for 8 and 9 . Addition of an O−H bond at the Sn=P-bond was found in reaction of water with phosphastannene 8 . Reaction with ammonia afforded the NH₃-adducts ( 21 – 23 ) at the tin atom for pnictastannenes 8 – 10 . Only in the case of the arsastannene an azide reaction product featuring a three membered Sn−As−N-ring was obtained.