锰(Ⅱ)催化氧化1，5-二(2-羟基-5-磺酸基苯)-3-氰基甲动力学及其应用

建立了一种测定痕量锰的新方法,并对反应的最佳条件、动力学参数及反应机理进行探讨,建立了反应动力学方程。方法测定 Mn(Ⅱ)范围 0.00～1.00 ng/mL,检出限 8.5×10-12 g/mL。方法可用于一次蒸馏水和井水中痕量锰的测定。     

测定痕量锰的锰(Ⅱ)-锌试剂-重铬酸钾体系催化分光光度法

在Na2B4O7-NaOH缓冲介质及加热条件下 ,锰 (Ⅱ )对重铬酸钾氧化锌试剂引起褪色 ,有明显的催化作用 ,据此建立了测定痕量锰的新方法 ;该法的线性范围为0.69～40μg/L,检出限为0.22μg/L ,反应表观活化能为87.1kJ/mol,反应表观速率常量1.10×10-3/s,用该法测定蒙药样品中锰含量 ,结果令人满意     

H2O2-天青Ⅱ催化动力学光度法测定痕量铜(Ⅱ)

在氨水介质中及加热条件下,痕量铜(Ⅱ)对H2O2氧化天青Ⅱ的褪色反应具有强烈的催化作用.探讨了最佳实验条件,据此建立了催化动力学光度法测定痕量铜(Ⅱ)的新方法.在选定的实验条件下,非催化反应与催化反应的吸光度差值△A与铜(Ⅱ)离子的质量浓度在16～56 μg/L范围内有良好的线性关系,检出限为9.36×10-11 g/mL.并且测定了催化反应的动力学参数,反应为准一级反应.在75℃下的表观速率常数为K'=4.04×10-3 8-1,表观活化能为74.54 kJ/mol.方法用于人发中痕量铜(Ⅱ)的测定,回收率在99.7%～100.0%之间.     

催化动力学光度法测定痕量锰

在活化剂氨三乙酸存在下,基于锰(Ⅱ)催化高碘酸钾氧化亮绿SF的反应,建立了测定痕量锰(Ⅱ)的催化动力学光度法。在优化的实验条件下,测定锰(Ⅱ)的线性范围为0.6~6.0 ng/mL,检出限为6.0×10-11g/mL,相对标准偏差为2.5%(n=9)。该法灵敏度高,选择性和重现性较好,已用于测定饮用水和葡萄酒试样中的痕量锰。     

偶氮胂I-高碘酸钾催化光度法测定痕量Mn(Ⅱ)

研究了在HAc—NH4Ac介质中，以1，10-菲啰啉为活化剂，锰(Ⅱ)催化高碘酸钾氧化偶氮胂I褪色反应的条件及影响因素，建立了动力学光度法测定痕量Mn(Ⅱ)的新方法。方法线性范围为0-80μg/L，检出限为6．3ng/mL，对60μg/L,Mn(Ⅱ)测定的相对标准偏差为2．6％。导出了动力学方程，该催化反应的表观活化能为130．4kJ／mol。已用于野菜、水果样品中锰(Ⅱ)的测定。     

催化光度法测定痕量猛——高碘酸钾-Mn(Ⅱ)-邻菲啰啉-溴酚蓝体系

本文以高碘酸钾-溴酚蓝为指示反应,在活化剂邻菲(口罗)啉存在下建立了催化光度法测定痕量锰(Ⅱ)的新方法,方法灵敏度为6×10~4μg/ml。线性范围为0.00—0.60μg/15ml,应用于标准铝合金及茶叶中痕量锰的测定,结果令人满意。     

鲁米诺-锰(Ⅱ)-高碘酸钾化学发光体系测定痕量锰的研究

本文提出1种以三乙醇胺作活化剂,基于鲁米诺-锰(Ⅱ)-高碘酸钾化学发光体系高灵敏度、高选择性测定痕量锰的分析方法。检测限达8×10^-6μg/mLMn(Ⅱ)。Mn(Ⅱ)浓度在10^-5～0.1μg/mL范围内呈良好的线性关系。测定1.0×10^-3μg/mLMn(Ⅱ)的相对标准偏差小于±3％。应用于井水及人发样品中锰的测定,结果令人满意。     

以N-十二烷基二甲基铵基乙酸为增敏剂催化光度法测定痕量锰

报道了以氨三乙酸为活化剂,以N-十二烷基二甲基铵基乙酸(DDMAA)为增敏剂,高碘酸钾氧化天青(Ⅱ)催化光度法测定痕量锰的新方法.本法在两性表面活性剂DDMAA存在下,灵敏度提高了3.3倍(锰量为 0.4～2.0 μg/L)和 5.6倍(锰量为2.0～6.0μg/L);相对标准偏差为1.3%(n=11),方法的检出限为5.2×10~(-11)g/mL.可用于茶叶中锰的测定.     

纳米钛酸锶钡粉体吸附富集-火焰原子吸收光谱法测定水样中锰离子

提出了纳米钛酸锶钡粉体吸附富集,火焰原子吸收光谱法测定水中痕量锰的含量。在pH 6的氨性缓冲介质中,采用纳米钛酸锶钡(0.02 g)对水样(10 mL)中的锰离子振荡吸附15 min。优化条件下吸附容量达5.4 mg.g-1。方法检出限(3s/k)为2.1μg.L-1。用0.15 mg.L-1锰(Ⅱ)标准溶液连续测定6次,求得其相对标准偏差(n=6)为3.4%。用于河水和地下水中痕量锰的测定,用标准加入法测得方法的回收率在93.5%~99.7%之间。     

催化动力学分光光度法测定痕量锰(Ⅱ)

研究了氢氧化钠介质中 ,痕量锰催化过氧化氢氧化桑色素褪色反应及其动力学条件 ,建立了催化动力学测定痕量锰的新方法。Mn (Ⅱ )的测定线性范围为 0 0 0 5～ 0 0 60 μg/2 5mL ,检出限为 7 8× 1 0 - 10 g·mL- 1。用于大米中痕量Mn (Ⅱ )的测定 ,结果满意。     

Sc2MgGa2 and Y2MgGa2

Scandium magnesium gallide, Sc₂MgGa₂, and yttrium magnesium gallide, Y₂MgGa₂, were synthesized from the corresponding elements by heating under an argon atmosphere in an induction furnace. These intermetallic compounds crystallize in the tetragonal Mo₂FeB₂‐type structure. All three crystallographically unique atoms occupy special positions and the site symmetries of (Sc/Y, Ga) and Mg are m2m and 4/m, respectively. The coordinations around Sc/Y, Mg and Ga are pentagonal (Sc/Y), tetragonal (Mg) and triangular (Ga) prisms, with four (Mg) or three (Ga) additional capping atoms leading to the coordination numbers [10], [8+4] and [6+3], respectively. The crystal structure of Sc₂MgGa₂ was determined from single‐crystal diffraction intensities and the isostructural Y₂MgGa₂ was identified from powder diffraction data.     

Zur Kenntnis der Dialkalimetalldichalkogenide β-Na2S2, K2S2, α-Rb2S2, β-Rb2S2, K2Se2, Rb2Se2, α-K2Te2, β-K2Te2 und Rb2Te2

On Dialkali Metal Dichalcogenides β-Na₂S₂, K₂S₂, α-Rb₂S₂, β-Rb₂S₂, K₂Se₂, Rb₂Se₂, α-K₂Te₂, β-K₂Te₂ and Rb₂Te₂ The first presentation of pure samples of α- and β-Rb₂S₂, α- and β-K₂Te₂, and Rb₂Te₂ is described. Using single crystals of K₂S₂ and K₂Se₂, received by ammonothermal synthesis, the structure of the Na₂O₂ type and by using single crystals of β-Na₂S₂ and β-K₂Te₂ the Li₂O₂ type structure will be refined. By combined investigations with temperature-dependent Guinier-, neutron diffraction-, thermal analysis, and Raman-spectroscopy the nature of the monotropic phase transition from the Na₂O₂ type to the Li₂O₂ type will be explained by means of the examples α-/β-Na₂S₂ and α-/β-K₂Te₂. A further case of dimorphic condition as well as the monotropic phase transition of α- and β-Rb₂S₂ is presented. The existing areas of the structure fields of the dialkali metal dichalcogenides are limited by the model of the polar covalence.     

Crystal Structures of [Bu2Sn(O2PPh2)2], [Ph2Sn(O2PPh2)2], and [PhClSn(O2PPh2)OMe]2. Raman Spectra of [Ph2Sn(O2PPh2)2] and [PhClSn(O2PPh2)OMe]2

[(n‐Bu)₂Sn(O₂PPh₂)₂] ( 1 ), and [Ph₂Sn(O₂PPh₂)₂] ( 2 ) have been synthesized by the reactions of R₂SnCl₂ (R=n‐Bu, Ph) with HO₂PPh₂ in Methanol. From the reaction of Ph₂SnCl₂ with diphenylphosphinic acid a third product [PhClSn(O₂PPh₂)OMe]₂ ( 3 ) could be isolated. X‐ray diffraction studies show 1 to crystallize in the monoclinic space group P2₁/c with a = 1303.7(1) pm, b = 2286.9(2) pm, c = 1063.1(1) pm, β = 94.383(6)°, and Z = 4. 2 crystallizes triclinic in the space group , the cell parameters being a = 1293.2(2) pm, b = 1478.5(4) pm, c = 1507.2(3) pm, α = 98.86(3)°, β = 109.63(2)°, γ = 114.88(2)°, and Z = 2. Both compounds form arrays of eight‐membered rings (SnOPO)₂ linked at the tin atoms to form chains of infinite length. The dimer 3 consists of a like ring, in which the tin atoms are bridged by methoxo groups. It crystallizes triclinic in space group with a = 946.4(1) pm, b = 963.7(1) pm, c = 1174.2(1) pm, α = 82.495(6)°, β = 66.451(6)°, γ = 74.922(6)°, and Z = 1 for the dimer. The Raman spectra of 2 and 3 are given and discussed.     

Electrochemical study of (NEt4)2Cl2FeS2MoS2 and (NEt4)2Cl2FeS2MoS2FeCl2

Summary The ability of [MoS₄]^2–, anions to be used as ligands for transition metal ions has been widely demonstrated, especially with Fe²⁺. The present study has been restricted to linear complexes such as (NEt₄)₂ [Cl₂FeS₂MoS₂] and (NEt₄)₂[Cl₂FeS₂MoS₂FeCl₂]. Their electrochemical properties are described: upon electrochemical reduction, these compounds yield MoS₂, as a black precipitate, and an iron complex in solution, assumed to be [SFeCl₂]^2–. The electrochemical reduction goes through two electron transfers, coupled with the breakdown of the molecular skeleton: a DISPl and an ECE mechanism. Depending on the solvent, the following equilibrium may be observed: [Cl₄Fe₂MoS₄]^2–[Cl₂FeMoS₄]^2–+FeCl₂. The equilibrium constant, K_D, was evaluated by differential pulse polarography. K_D is tightly related to the donor number of the solvent.     

The alkali hypophosphites KH2PO2, RbH2PO2 and CsH2PO2

The structures of the hypophosphites KH₂PO₂ (potassium hypophosphite), RbH₂PO₂ (rubidium hypophosphite) and CsH₂PO₂ (caesium hypophosphite) have been determined by single‐crystal X‐ray diffraction. The structures consist of layers of alkali cations and hypophosphite anions, with the latter bridging four cations within the same layer. The Rb and Cs hypophosphites are isomorphous.     

Syntheses,Spectroscopic Studies,and Crystal Structures of Me2Sn(O2PPh2)2, Ph2Pb(O2PMe2)2, and Ph2Pb(O2PPh2)2

Me₂Sn(O₂PPh₂)₂ ( 1 ), Ph₂Pb(O₂PMe₂)₂ ( 2 ), and Ph₂Pb(O₂PPh₂)₂ ( 3 ) have been synthesized by the reactions of Me₂SnCl₂ or Ph₃PbCl with the corresponding diorganophosphinic acid in methanol. X‐ray diffraction studies show that the diorganophosphinate groups behave as double bridges between the metal atoms leading to polymeric ring‐chain structures with M₂O₄P₂ (M = Pb, Sn) eight‐membered rings. The organic groups bonded to the metal atoms are in trans‐position in the resulting octahedral arrangement around the metal atoms. The IR and the mass spectra were reported and discussed.     

Thermal decomposition of Me3SnO2PCl2, Me2Sn(O2PCl2)2 and Ph3SnO2PCl2

TG and DTA studies on Me₃SnO₂PCl₂, Me₂Sn(O₂PCl₂)₂ and Ph₃SnO₂PCl₂ were carried out under dynamic argon atmosphere. The results show that the decomposition proceeds in different stages leading to the formation of Sn₃(PO₄)₂ as a stable product. This compound was characterized by IR spectroscopy. Decomposition schemes involving reductive elimination reactions were proposed.