聚乙二醇-硫酸铵-铝试剂体系中镧、镨、镝的分离研究

研究了在聚乙二醇2000(PEG)-硫酸铵-铝试剂双水相体系中, 铝试剂作萃取剂, 对镧、镨、镝的萃取行为. 实验结果表明, 在pH1～7酸度条件下, La(Ⅲ)完全被PEG相萃取, 而Pr(Ⅲ)几乎不萃取, Dy(Ⅲ)部分被萃取. 在pH5的缓冲溶液中实现了La(Ⅲ)与Pr(Ⅲ)的分离. 通过加入表面活性剂, 测定溶液光谱等方法, 探讨了金属离子在聚乙二醇相中存在形态.     

聚乙二醇-硫酸铵-二甲酚橙体系萃取分离钯

研究了萃取剂二甲酚橙与Pd(Ⅱ)离子的螯合物在聚合物-硫酸铵-水体系中两相间的分配行为。在pH1．0～6．0条件下，Pd(Ⅱ)几乎被二甲酚橙完全萃取到PEG相中，而Fe(Ⅱ)、Co(Ⅱ)、Zn(Ⅱ)萃取率随pH变化显著，Mn(Ⅱ)、Cd(Ⅱ)基本不被萃取。在HClO4介质pH1．0～2．0条件下，实现了Pd(Ⅱ)与Fe(Ⅱ)、Co(Ⅱ)、Zn(Ⅱ)、Mn(Ⅱ)、Cd(Ⅱ)的定量萃取分离。     

聚乙二醇-硫酸铵-锌试剂体系中铜、镧、铀、铈萃取性能研究

对4种金属离子[铜（Ⅱ）,镧（Ⅲ）,铀（Ⅵ）及铈（Ⅳ）]在双水相液-液萃取体系[聚乙二醇2000（PEG）-（NH4）2SO4-锌试剂]中的萃取行为,特别是影响萃取的条件（包括溶液的酸度,锌试剂用量;硫酸铵加入量及有无表面活性剂存在等）作了研究。结果表明,铜（Ⅱ）在pH3～8的条件下,以锌试剂螯合物的形态被定量萃取进入PEG相,萃取率在95％以上;镧（Ⅲ）在pH1～7之间不被萃取,仍以离子状态留在下层水相中;而铀（Ⅵ）及铈（IV）在pH1～11范围内萃取不完全,萃取率在30％～65％之间。试验表明,在pH6的条件下,铜（Ⅱ）可与共存的镧（Ⅲ）定量分离,铜（Ⅱ）进入PEG相的萃取率在95．6％～98．3％之间,而共存的镧（Ⅲ）仅有4．5％～5．1％进入PEG相中。对锌试剂作为螯合剂与上述4种金属离子在萃取过程的反应机理作了初步探讨。     

铁钴镍铜锌镉铝在聚乙二醇—硫酸铵—茜素S体系中萃取分离

本文用茜素Ｓ作萃取剂，研究了Ｆｅ，Ｃｏ，Ｎｉ，Ｃｕ，Ｚｎ，Ｃｄ，Ａｌ在聚乙二醇－硫酸铵－茜素Ｓ体系中的非有机溶剂萃取行为。实验结果表明，在ｐＨ５的ＨＡｃ－ＮａＡｃ缓冲溶液中，Ｆｅ，Ａｌ与茜素Ｓ的络合物可被ＰＥＧ相几乎完全萃取，Ｃｕ，Ｎｉ部分被萃取，而Ｃｏ，Ｚｎ，Ｃｄ则不被萃取，从而实现了Ｆｅ与Ｃｏ，Ｚｎ，Ｃｄ及Ａｌ与Ｃｏ，Ｚｎ，Ｃｄ混合离子间的定量分离。     

硫酸铵-乙醇-铬天青S体系萃取分离铝

研究了硫酸铵-乙醇-铬天青S体系萃取分离和富集铝的行为及与一些金属离子分离的条件。硫酸铵能使乙醇的水溶液分成两相,在分相过程中,Al3+和铬天青S(CAS)生成的Al(CAS)2-能被乙醇相完全萃取,Pb2+、Pd2+、Cr3+、Ru3+、Ir4+、Ni2+、Mg2+、Co2+和Fe2+不被萃取而和Al3+分离。     

硫酸铵-碘化钾-乙醇体系萃取分离铋

1　引言利用高聚物水溶液在无机盐存在下可以分成两相的非有机溶剂萃取分离方法已引起人们的重视[1 ,2 ] 。本文研究发现 ,在硫酸铵存在下 ,乙醇与水分相过程中 ,Ｂｉ(Ⅲ )与Ｉ- 形成的ＢｉＩ3-6 络阴离子能被乙醇相定量萃取 ,控制一定的酸度 ,可以实现Ｂｉ(Ⅲ )与Ｆｅ(Ⅲ )、Ｃｏ(Ⅱ )、Ｍｎ(Ⅱ )、Ｃｕ(Ⅱ )、Ｎｉ(Ⅱ )、Ｍｏ(Ⅵ )之间的分离。该萃取体系与传统的有机溶剂萃取分离方法相比 ,具有平衡时间短 ,相分离速度快 ,无三相乳化 ,不使用有毒害有机溶剂 ,操作简单 ,快速均相萃取 异相分离等优点 ,既能萃取离子缔合物 ,又能萃取络阴…     

硫酸铵-碘化钾-乙醇体系萃取分离钯

传统的萃取分离法主要是采用与水互不相溶的有机溶剂作萃取溶剂,有的反应速度慢,传质速率低,分配比较小而需要在振荡器上进行较长时间振荡或多次萃取才能达到定量萃取的目的。均相萃取、异相分离萃取体系可以克服异相萃取分离技术中的一些缺点而受到重视[1,2]。本文以乙醇为萃取溶剂,均相萃取、异相分离Pd(Ⅱ)。试验表明硫酸铵存在下乙醇与水分相过程中,Pd(Ⅱ)与I-开成的PdI42-与质子化乙醇(C2H5OH2+)形成电中性的缔合物(C2H5OH2+)2·PdI42-被乙醇相萃取,能使Pd(Ⅱ)从Fe(Ⅲ)、Al(Ⅲ)、Zn(Ⅱ)、Mn(Ⅱ)、Ni(Ⅱ)、Cr(Ⅲ)、Co(Ⅱ)…     

硫酸铵-溴化钾-乙醇体系萃取分离金

研究了(NH4)2SO4存在下,KBr-乙醇体系萃取分离Au(Ⅲ）的行为。实验表明,Br^-与Au(Ⅲ）形成的AuBr4^-很容易被萃取到乙醇相中。当溶液中KBr、(NH4)2SO4和无水乙醇浓度分别为0．04g／mL、0．30g／mL、30％(V／V),pH=2—4时能使Au(Ⅲ）的萃取率达到100％,Al（Ⅲ）、Ni(Ⅱ)、Mn(Ⅱ)、Cr（Ⅲ）、Co(Ⅱ)、Fe（Ⅲ）、Zn(Ⅱ)、Cu(Ⅱ)、Mo（Ⅵ)、U(Ⅳ)基本不被萃取,实现了Au（Ⅲ）与上述离子的分离。     

硫酸铵-溴化钾铵-正丙醇体系萃取分离和富集锗的研究

研究了硫酸铵-溴化钾铵-正丙醇体系萃取分离和富集锗的行为及与一些金属离子分离的条件.硫酸铵能使正丙醇的水溶液分成两相,在分相过程中,Ge4+与KBr生成(GeBr62-),并与质子化正丙醇(C3H7OH2+)形成缔合物[GeBr62-][C3H7OH2+]2,此缔合物能被正丙醇相完全萃取.当正丙醇、KBr和硫酸铵的浓度分别为30％(V/V)、7.0×10-3mol/L、0.20g/mL时,(GeBr62-)的萃取率达到97.7％以上,而Ni2,Pb2,Cr3+,Co2,Fe3+,Al3+,Mg2+,Ag+,Bi3+,CH2,W(Ⅵ)和V(Ⅴ)基本不被萃取,实现了Ge4+与上述金属离子的分离.     

硫酸铵-硫氰酸铵-乙醇体系萃取分离铂

从pH 3.0的水溶液中,在较大量的硫酸铵存在下,Pt(Ⅳ)以Pt(SCN)62-形式定量萃取入乙醇中。萃取体系中各试剂的适宜用量为硫氰酸铵溶液20 g.L-1,硫酸铵溶液300 g.L-1,乙醇0.30 mL.mL-1,按此条件可达到Pt(Ⅳ)与适量的Ni(Ⅱ),Cr(Ⅲ),Co(Ⅱ),Fe(Ⅱ),Mn(Ⅱ),Al(Ⅲ),Rh(Ⅲ)等离子分离。此方法已用于催化剂Ni-Pt/Al2O3试样分析中作为分离手段。对一件上述催化剂试样进行5次测定,测得铂的平均结果为w(Pt)0.104%,RSD为1.7%。     

Chromatographic separation of inorganic ions on thin layers of lanthanum silicate ion-exchanger

Summary Thin layers of lanthanum silicate have been used to study the chromatographic behaviour of 28 metal ions in aqueous and mixed systems. As³⁺, Mo⁶⁺, Sb³⁺, Ti⁴⁺ and others can be easily separated from a number of inorganic ions. Fast ternary and binary separations have also been achieved and various separations are discussed. It is shown that Alberti's relation is also obeyed by thin layers of lanthanum silicate. Presented at the 21^st ISC held in Stuttgart, Germany, 15^th–20^th September, 1996     

Ion imprinted polymer particles: synthesis, characterization and dysprosium ion uptake properties suitable for analytical applications

Dysprosium(III) ion imprinted polymer particles were prepared by the copolymerization of styrene monomers and a crosslinking agent divinylbenzene in the presence of dysprosium(III)-5,7-dichloroquinoline-8-ol-4-vinyl pyridine ternary complex wherein dysprosium(III) ion is the imprint ion and is used to form the imprinted polymer. The dysprosium(III) ion was removed from polymer particles by leaching with 1:1 HCl which leaves a cavity in the polymer particles. The polymer particles both prior to and after leaching have been characterized by IR, TGA, DTA and XRD studies. The leached particles selectively preconcentrated dysprosium ion from dilute aqueous solutions as determined spectrophotometrically using Arsenazo-I as reagent. The optimum pH value for quantitative enrichment is 6-9 and desorption can be achieved by using 25 ml of 1 mol/l of HCl. The retention capacity of the polymer particles was found to be 40.15 mg/g, which is much higher than MIPs prepared by other imprinting techniques. The dysprosium ion imprinting polymer gave 40 times higher distribution ratio for dysprosium ion compared to blank polymer. More significantly the selectivity coefficients of dysprosium compared to other lanthanides results in enhancement by 60-180-fold. The separation factors with respect to other selected lanthanides were also compared with liquid-liquid extractive separation using di-2-ethylhexyl phosphoric acid (D2EHPA) as extractant. The selectivity of dysprosium ion imprinting polymer (IIP) particles for dysprosium over yttrium is much higher and comparable in case of Nd and Lu when compared to conventional extractant such as D2EHPA in liquid-liquid extraction (LLE). Five replicate determinations of 50 μg of dysprosium present in 250 ml of sample gave a mean absorbance of 0.150 with a relative standard deviation of 2.42%. The detection limit corresponding to three times the standard deviation of the blank was found to be 2 μg/250 ml.     

Ultratrace determination of europium in high-purity lanthanum, praseodymium and dysprosium oxides by luminescence spectrometry

A luminescence spectrometric method was developed for the determination of ultra trace amounts of europium (down to 1 x 10(-13) M) in high purity lanthanum, praseodymium and dysprosium oxides. This is based on the enhanced luminescence of europium-thenoyltrifluoroacetone (TTA)-dibenzo-18-crown-6 (DBC)-Triton X-100 in the presence of terbium. The fluorescence intensity is linear with europium concentration in the range 1 x 10(-11) - 1 x 10(-6) M under the recommended conditions. The optimized procedure is successfully utilized for the determination of ultratrace amounts of europium in lanthanium, praseodymium and dysprosium oxides.     

TOPO萃取色谱分离钨,钼的研究

研究了用TOPO的二甲苯溶液从盐酸水溶液中单取分离钨、钼的条件,测定了萃取配合物的组成及萃取平衡常数,提出了分离钨、钼的萃取色谱法,并用于合金钢及地球化学样品中钨和钼的测定。     

Determination of praseodymium in lanthanum compounds by neutron activation and ion exchange separation

Summary A procedure was developed to determine small amounts of praseodymium in lanthanum compounds by neutron activation analysis. After irradiation of the sample in a reactor praseodymium is separated from lanthanum by anion exchange and Pr-142 is measured by a gamma-ray spectrometer. From the high decontamination factor of 110⁸ a detection limit of 5ppb praseodymium in lanthanum may be calculated. Because of the strong activation of lanthanum, the handling of samples with activities of about 1 Ci La-140 would be required. For the analyses carried out here with respect of sample weights, neutron flux and irradiation time a detection limit of 2.4ppm was obtained.

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Bestimmung von Praseodym in Lanthanverbindungen durch Neutronenaktivierung und Ionenaustausch

Zusammenfassung Zur Bestimmung von geringen Mengen Praseodym in Lanthanverbindungen wurde ein auf Neutronenaktivierungsanalyse basierendes Verfahren entwickelt. Nach Bestrahlung der Probe im Reaktor wird Praseodym mit einem Anionenaustauscher von Lanthan getrennt und Pr-142 mit einem Gamma-Spektrometer gemessen. Der mit der Trennung erreichte Reinigungsfaktor von 110⁸ würde eine Nachweisgrenze von etwa 5ppb Praseodym in Lanthan erlauben. Wegen der starken Aktivierung des Lanthans würde das aber den Umgang mit Proben von ca. 1 Ci La-140 erfordern. Mit den hier gewählten Probenmengen, Neutronenflüssen und Bestrahlungszeiten wurde eine Nachweisgrenze von 2,4ppm erreicht.

Presented at the Ulmer Symposium Analytische Chemie — Elementanalyse mit chromatographischen Methoden, Sept. 19–21, 1979, D-7900 Ulm     

Furfuroxides of lanthanum,praseodymium, neodymium,and samarium

Ln(R)₃, Ln(R)₂(OPrⁱ), and Ln(R)(OPrⁱ)₂ (where Ln = La, Pr, Nd, and Sm; R = deprotonated furfuryl alcohol, RH) were prepared from lanthanide isopropoxide and furfuryl alcohol in 1:3, 1:2 and 1:1 stoichiometric ratios respectively in anhydrous benzene under reflux. Ln(R)₂-(OPrⁱ) and Ln(R)(OPrⁱ)₂ were also obtained at room temperature. The isopropoxy group(s) of these derivatives were replaced by tertiary butoxy group(s) during the alcohol exchange reactions with tertiary butanol. All these derivatives are soluble in benzene except the tertiary butoxy derivatives which are only sparingly soluble. However, they become insoluble on standing. These furfuroxides did not distil at ～300°C/10² torr but decomposed. Isopropoxy/butoxy furfuroxides were characterized by the elemental analysis and also by estimating the liberated isopropanol. The i.r. spectra of Ln(R)₃ clearly supports the presence of furfuroxide groups in these derivatives.     

用回归正交法从混合稀土-二甲酚橙极谱体系中同时测定镧、铈、镨、钕的研究

本文用回归正交设计安排镧、铈、镨和钕四种稀土元素的多因素一次回归正交实验,测定稀土与二甲酚橙形成的极谱络合物吸附波。然后,对四种稀土浓度对导数波高进行正交回归分析,求得回归方程。对该方程及其各项系数进行方差分析,F检验的显著性水平不大于0.01。实验说明共存稀土之间呈现强烈的交互作用,回归方程的乘积项系数的显著性很高。所以,应用求解该方程的偏微方程组的方法,测定了包头混合稀土氧化物中四种单一稀土的含量。     

Extraction and isolation of catechins from tea

Tea is a major source of catechins, which have become well known for their antioxidant potential. Numerous human, animal, and in vitro studies have linked tea catechins with prevention of certain types of cancers, reduction of the risks for obesity, diabetes, and cardiovascular disease, and improvement of the immune system. Tea catechins are widely used in various neutraceuticals, pharmaceuticals, and cosmetics for either enhancing product shelf-life or for enhancing human health. Thus, the demand for catechins has increased considerably. Catechins have been extracted and isolated from tea leaves by numerous methods through several steps including: treatment of the tea leaves, extraction of catechins from teas into solvents, isolation of catechins from other extracted components, and drying the preparations to obtain catechin extracts in a powder form. This paper outlines the physical and chemical properties of the tea catechins and reviews the extraction steps of the various extraction methods, as a basis to improve and further develop the extraction and isolation of the tea catechins.     

New nano-particle La(III) supramolecular compound as a precursor for preparation of lanthanum oxybromide-, hydroxide-, and oxide-nanostructures

Nano-particles of a new La(III) supramolecular compound [La(4,4′-bipy)(H₂O)₂(NO₃)_3.75Br_0.25] · (4,4′-Hbipy) (1), have been synthesized from reaction of 4,4′-bipy with La(NO₃)₃ and NaBr by the sonochemical method. For the first time LaOBr, La(OH)₃ and La₂O₃ nano-structures were prepared from [La(4,4′-bipy)(H₂O)₂(NO₃)_3.75Br_0.25] · (4,4′-Hbipy) (1) by calcination at 400, 500, and 700°C, respectively. The structure of 1 was determined by X-ray crystallography and the nano-structures were characterized by X-ray powder diffraction (XRD) and scanning electron microscopy (SEM). Thermal stabilities of nano and crystal samples of 1 were studied and compared with each other.