Zn-5-溴水杨基荧光酮-酒石酸钠-CTMAB 四元显色体系的研究与应用

研究了在碱性介质中 ,Zn-5 -溴水杨基荧光酮 -酒石酸钠 -CTMAB体系光度法测定微量锌的新方法。四元体系的最大吸收峰在 5 6 0 nm处 ,表观摩尔吸光系数为 1.0 8× 10 5 L·mol-1·cm-1。配合物的稳定常数 K′稳 =1.6 7× 10 1 2 ,锌含量在 0～ 10μg/2 5 m L范围内符合比耳定律。此法已用于水样和药物中锌含量的直接测定     

用2，4，6-三（3，5-二甲基吡唑）-1，3，5-三嗪碳糊修饰电极测定痕量Zn（Ⅱ）

用2,4,6 -三 (3,5 -二甲基吡唑 ) -1,3,5-三嗪 (TDT)制得了碳糊修饰电极 ,在pH=5的HAc -NaAc的缓冲溶液中,将锌富集在电极上,用差示脉冲阳极溶出伏安法测定锌,锌(Ⅱ)的浓度在3.0×10-8～4.0×10-5mol·L-1 范围内与峰高呈良好的线性关系。该电极可用于测定自来水中锌的含量,获得满意的效果。     

1,5-二(2-羟基-5-氯苯)-3-氰基甲(月替)光度法测定药物中微量锌和铜

研究了显色剂1,5-二(2-羟基-5-氯苯)-3-氰基甲(月替)(HCPCF)光度法同时测定锌和铜的方法.分别在pH 7.0乙酸铵和pH 3.6乙酸-乙酸钠介质中,Triton X-100存在下,锌和铜与HCPCF分别形成稳定的1∶1蓝色络合物,最大吸收波长分别为645nm和620nm,表观摩尔吸光系数分别为3.16×104L·mol-1·cm-1和3.10×104L·mol-1·cm-1,在0～30μg/25ml浓度范围内均符合比耳定律.可直接用于药物中微量锌和铜的测定.方法准确、快速、简便.     

5-Br-PADCAP分光光度法测定血清锌

为建立快速、简便、灵敏的分光光度法测定血清锌 ,在表面活性剂TritonX -1 0 0存在下 ,用 2 -(5 -溴 -2 -吡啶偶氮 ) -5 -[N ,N -二羧基甲基 ]苯酚 (5 -Br-PADCAP)作显色剂 ,不去蛋白分光光度法测定血清锌。结果表明 ,锌络合物最大吸收波长为 5 5 7nm ,线性范围 0～ 5 0 0μmol L ,摩尔吸光系数为 1 1 2× 1 0 5L·mol-1·cm-1。回收率为 99 9% ,批内变异系数 (CV)为2 1 % ,批间变异系数为 2 9% ,与原子吸收分光光度法 (x)比较具有良好的相关性 ,y =1 0 1 0x-0 1 5 4,r=0 991 8,P >0 0 5。可见本法测定血清锌不必去蛋白、用血量少、方法简便、灵敏可靠 ,适合临床应用     

3,5-diCl-DMPAP光度法同时测定铜和锌

研究了在乳化剂OP存在下,以2 (3,5 二氯 2 吡啶偶氮) 5 二甲氨基酚(3,5 diCl DMPAP)为显色剂使铜和锌同时显色,再以硫脲 硫代硫酸钠掩蔽铜,利用两次所测吸光度之差以差减法同时测定铜、锌。试验结果表明,pH6.0～10.0时,铜和锌与试剂均形成1∶2的紫红色配合物。铜配合物的最大吸收波长位于558nm处,锌配合物的最大吸收波长位于565nm处。两者在562nm波长处的吸光度具有良好加和性,其表观摩尔吸光系数分别为εCu=9.6×104L·mol-1·cm-1,εZn=1.2×105L·mol-1·cm-1。方法灵敏度高、操作简单,用于地质化探样品和人发中微量铜、锌的同时测定,结果满意。     

紫外光谱区分光光度法测定微量铁

铁与磺基水杨酸在pH5.6～6.0范围内形成的1:2络合物,在紫外光谱区波长约248nm处有一尖形吸收峰,灵敏度很高,摩尔吸光系数ε=2.82×10~4L·mol~(-1)·cm~(-1),比可见光区ε=4.25×10~3L·mol~(-1)·cm~(-1)提高了5倍,利用导数法可以提高到ε=1.20×10~5L·mol~(-1)·cm~(-1),是可见光区的24倍。     

新试剂1-(2,6-二溴-4-硝基苯)-3-(4-硝基苯)-三氮烯与汞的显色反应及应用

三氮烯试剂与第ＩＢ、ＩＩＢ族金属元素有高灵敏的显色反应 1 [1] ,可用来测定样品中微量的Ｃｄ2 + 、Ｈｇ2 + 、Ｚｎ2 + 、Ｎｉ2 + 。随着表面活性剂引入该显色体系 ,使该试剂与金属离子显色反应的灵敏度有了很大的提高。目前报道的三氮烯显色剂与Ｈｇ2 + 显色反应的灵敏度一般在ε =1 .0× 1 0 5Ｌ·ｍｏｌ-1·ｃｍ-1左右 ,但也有部分试剂的灵敏度较高 ,如ＯＣ Ｃａｄｉｏｎ[2 ] 的ε =1 .77× 1 0 5Ｌ·ｍｏｌ-1·ｃｍ-1,ＤＮＡＡＢ[3 ] ε=1 .74× 1 0 5Ｌ·ｍｏｌ-1·ｃｍ-1,ＭＤＡＡ[4]的ε=1 .8× 1 0 5Ｌ·ｍｏｌ-1·ｃｍ-1,ＡＰＤ…     

5,3′,5′-三磺酸基-2,3,4,4′-四羟基脱氧安息香三钠盐的合成、晶体结构及性质研究

合成了水溶性很好的5,3′,5′-三磺酸基-2,3,4,4′-四羟基脱氧安息香三钠盐(TTDB),采用IR、UV、1HNMR和元素分析对其结构进行了表征,并利用X射线单晶衍射仪测定了该化合物的晶体结构.使用荧光光谱法检测了化合物对羟基自由基的清除作用.用循环伏安法探讨了化合物的电化学性质.实验结果表明,5,3′,5′-三磺酸基-2,3,4,4′-四羟基脱氧安息香三钠盐[C14H17Na3O18S3]属于单斜晶系,空间群C2/c,a=1·4223(4)nm,b=2·4327(8)nm,c=1·3596(4)nm,α=90°,β=113·044(5)°,γ=90°,Z=8,V=4·329(2)nm3,Dc=1·925Mg/m3,F(000)=2568,Mr=627·43,R1=0·0950,wR2=0·2648.TTDB的抗羟基自由基的氧化作用优于其相应的脱氧安息香THDB,前者清除羟基自由基的半数有效浓度(EC50)为47·3μmol/L,而后者的EC50则为53·1μmol/L.电化学研究结果表明,THDB和TTDB的氧化还原过程有所差异,前者负扫时在-1·016和-1·228V处出现两个还原峰,正扫时在0·219V处出现一个氧化峰,但后者负扫时仅在-0·999V出现一个还原峰,正扫时在0·193V出现一个氧化峰.     

螯形主体分子的设计、包结性能及其在细辛挥发油 有效成分选择分离中的应用

设计了两种新的具有螯形骨架的主体分子反式-1,2-二苯基-1,2-苊二醇(1)和顺式-1,2-二(1'-萘基)-1,2-苊二醇(2),主体(1),(2)可与许多有机小分子化合物形成配位包合物。用IR和粉末XRD表征了主体分子(1)和(2)的包结物,用^1NMR测定了包结物的主客体分子摩尔比：(1)·DMF(1:2),(1)·DMSO(1:2),(1)·THF(1:2),(1)·二氧六环(1:1),(1)·吡啶(1:1),(2)·DMF(1:1)和(2)·DMSO(1:1)。单晶X射线衍射分析了包结物的晶体结构,(1)·DMF：空间群Pnaa,a=0.9377(1)nm,b=1.4351(1)nm,c=4.0463(3)nm;(1)·DMSO：空间群Pbcn,a=1.6278(1)nm,b=1.0751(1)nm,c=1.4980(1)nm;(2)·DMF：P2~1/n,a=0.9796(1)nm,b=1.2377(1)nm,c=2.2344(3)nm,β=93.02(1)°;游离主体(1)：空间群P1,a=1.0461(1)nm,b=1.1213(1)nm,c=1.5496(1)nm,α=81.74(1)°,β=75.71(1)°,γ=89.00(1)°;分析了主体分子的刚性和柔韧性对包结性能的影响。并研究了主体分子(1)选择分离细辛挥发油,将顺甲基异丁香酚从挥发油中分离出来。     

螯形主体分子的设计、包结性能及其在细辛挥发油 有效成分选择分离中的应用

设计了两种新的具有螯形骨架的主体分子反式-1,2-二苯基-1,2-苊二醇(1)和顺式-1,2-二(1'-萘基)-1,2-苊二醇(2),主体(1),(2)可与许多有机小分子化合物形成配位包合物。用IR和粉末XRD表征了主体分子(1)和(2)的包结物,用^1NMR测定了包结物的主客体分子摩尔比：(1)·DMF(1:2),(1)·DMSO(1:2),(1)·THF(1:2),(1)·二氧六环(1:1),(1)·吡啶(1:1),(2)·DMF(1:1)和(2)·DMSO(1:1)。单晶X射线衍射分析了包结物的晶体结构,(1)·DMF：空间群Pnaa,a=0.9377(1)nm,b=1.4351(1)nm,c=4.0463(3)nm;(1)·DMSO：空间群Pbcn,a=1.6278(1)nm,b=1.0751(1)nm,c=1.4980(1)nm;(2)·DMF：P2~1/n,a=0.9796(1)nm,b=1.2377(1)nm,c=2.2344(3)nm,β=93.02(1)°;游离主体(1)：空间群P1,a=1.0461(1)nm,b=1.1213(1)nm,c=1.5496(1)nm,α=81.74(1)°,β=75.71(1)°,γ=89.00(1)°;分析了主体分子的刚性和柔韧性对包结性能的影响。并研究了主体分子(1)选择分离细辛挥发油,将顺甲基异丁香酚从挥发油中分离出来。     

Flow-injection spectrophotometric determination of cadmium with quinolylazo compound after on-line separation using a silica gel column

2-[2-(4-Methylquinolyl)azo]-5-diethylaminophenol(QADP) reacts with cadmium in aqueous ethanol and the molar absorptivity of the QADP-cadmium complex is the highest (1.51 x 1O(5)M(-1) cm(-1), gamma(max) 569 nm) of the reagents reported previously. A flow-injection spectrophotometric determination of cadmium with QADP after on-line separation using silica gel column was proposed. A 450 mug/l cadmium concentration could be determined in the presence of 13 mg/l zinc, 83 mg/l lead and 11 mg/l iron.     

Spectrophotometric determination of zinc with 2-(3,5-dibromo-2-pyridylazo)-5-diethylaminophenol in the presence of anionic surfactant

A sensitive spectrophotometric method for zinc has been established by reacting zinc with 2-(3,5-dibromo-2-pyridylazo)-5-diethylaminophenol (3,5-diBr-PADAP) in the presence of an anionic surfactant, sodium lauryl sulphate. The molar absorptivity is 1.3 x 10(5) l.mole(-1).cm(-1) at 570 nm. The molar ratio of zinc to 3,5-diBr-PADAP is 1:2. Beer's law is obeyed up to 0.7 ppm of zinc. With preseparation of zinc by extraction of its thiocyanate complex, the method has been applied to the determination of zinc in waste water.     

Determination of cobalt in the presence of high concentrations of zinc by differential pulse polarography

Summary Cobalt(II) can be determined in 0.1 mol/l Na₃citrate + 0.1 mol/l NH₄Cl + 0.08% dimethylglyoxime as supporting electrolyte in the presence of a 50 000-fold excess of zinc by differential pulse polarography. The limit of determination is 4.2×10^–5 mol/l Co (2.5 mg/l). Linear calibration curves are obtained within the range of 1×10^–7 to 5×10^–6 mol/l cobalt without zinc and in the presence of 5×10^–3 mol/l Zn. The analytical method developed is suitable for the determination of cobalt in zinc plant solutions.

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Cobaltbestimmung in Gegenwart hoher Zinkkonzentrationen mit Hilfe der Differential-Puls-Polarographie

     

Ion-exchanger colorimetry-VI Microdetermination of nickel in natural water

Ion-exchanger colorimetry with 1-(2-pyridylazo)2-naphthol (PAN) has been developed for the determination of nickel at the mug/l. level in natural water. With 1 litre of sample the detection limits are 1.3 x 10(-9)Mi.e., 0.077 mug/l. for fresh water and 5.8 x 10(-9)Mi.e., 0.34 mug/l. for sea-water. The distribution ratio is 5 x 10(4). Copper and zinc, which form coloured species with PAN in the resin phase, can be completely eluted with a masking solution composed of EDTA and thioglycollic acid (pH 7.8). Cobalt can be determined simultaneously by measurement at 628 nm.     

Spectrophotometric determination of zinc in copper-base alloys with TAN

TAN reacts with zinc(II) forming a red complex with composition 1:2 Zn(II)-TAN and absorption maximum at 582 nm. Zinc can be determined with this reagent in the presence of Triton X-100, in the pH range 6.20-8.00 with a molar absorptivity of 4.5×10⁴ l/mol/cm Beer's Law was obeyed up to least 1.55 g/ml. Copper interference was eliminated with a mixture of thiosulfate and ascorbic acid and nickel separated by precipitation with dimethylglyoxime. The proposed method was used for zinc determination in several copper-base alloys and the results of analysis in comparison with certified values indicated that the procedure was accurate and precise. A derivative procedure is also proposed, allowing zinc determination with high sensitivity (5-400 ng/ml).     

具有二维网格结构的5-(4-硝基苯基)四唑-锌(Ⅱ)配合物

A zinc(Ⅱ) complex [(5-(4-nitrophenyl)tetrazolato)₂Zn]_n was obtained by the hydrothermal treatment of ZnBr₂ and NaN₃ with 4-nitrobenzonitril in water at 120 ℃ in Pyrex tube. The crystal belongs to orthorhombic system with space group Pbcn, and a=1.040 7(5) nm, b=1.382 1(7) nm, c=2.435 1(13) nm, V=3.503(3) nm³, Z=8. This complex is a good blue fluorescent material in solid state at room temperature. CCDC: 684226.     

Spectrophotometric determination of zinc with hydrazidazol in the presence of Triton X-100 and its application in metal analysis

A new spectrophotometric method for the determination of zinc is proposed. The chromogenic agent Hydrazidazol forms a 1:1 chelate with zinc in the presence of Triton X-100 in a medium containing 20-40% ethanol. The molar absorptivity and conditional formation constant have been found to be 2.7 x 1O(4) l.mole(-1).cm(-1) (at 640 nm) and 10(5.32) respectively. Beer's law is obeyed for zinc over the range of 0.2-0.8 mug/ml with a standard deviation of 0.024 mug/ml. The method can be applied to the determination of zinc in cadmium metal and its oxide after preconcentration by selective extraction of zinc thiocyanate into ethyl acetate in the presence of EDTA and thiosulphate as masking agents.     

Extraction and spectrophotometric determination of zinc in coal fly ash and pond sediments with 2-[2-(3,5-dibromopyridyl)azo]-5-dimethylaminobenzoic acid

An extraction-spectrophotometric method is described for the determination of traces of zinc with 2-[2-(3,5-dibromopyridyl)azo]-5-dimethylaminobenzoic acid. The reagent forms a stable, blue 1:2 zinc/reagent complex that can be extracted into chloroform. The apparent molar absorptivity of the zinc(II) complex is 1.26 × 10⁵ l mol^?1 cm^?1 at 610 nm in chloroform. The reagent is relatively selective; interferences from cobalt, copper and nickel can be masked with dimethylglyoxime and aluminium and iron with a mixture of sodium fluoride and triethanolamine. The method is applied to the determination of zinc in coal fly ash and pond sediments with good precision and accuracy.     

Spectrophotometric determination of indium in nickel alloys and zinc ores with 1-(2-pyridylmethylideneamine)-3-(salicylideneamine)thiourea

A sensitive method for the spectrophotometric determination of indium with 1-(2-pyridylmethylideneamine)-3-(salicylideneamine)thiourea is proposed. A yellow complex is formed at pH 4.5 (succinate buffer) in a medium containing 40% dimethylformamide, and the absorbance is measured at 415 nm. The molar absorptivity is 6.2 x 10(4)l.mole(-1).cm(-1). The relative standard deviation of the procedure is 1.5%. The method has been applied to determination of indium in a nickel alloy and three zinc ores, with prior isolation of indium by co-precipitation with ammonia and extraction into n-butyl acetate from 5M hydrobromic acid.     

Differential pulse polarographic determination of selenium(IV) in whole blood using the catalytic hydrogen wave

The selenium content in blood was determined using the hydrogen catalytic peak. This peak at -1.1 V was obtained in the presence of selenium and molybdenum at pH values of 1-4 in different buffers. For the determination of selenium, the Mo(VI) concentration has to be approximately 100-200 times higher than the selenium present. The linear domain range of selenium is 1x10(-6)-5x10(-9) M. The interference of zinc is eliminated by the addition of EDTA at pH 3.5 acetate buffer. The method was applied to 1.0 ml of digested blood, and 620+/-44 mug l(-1) Se and 7.15 mg l(-1) Zn could be determined with a 90% (n=6) confidence interval.