Role of reaction atmosphere in preparation of potassium tantalate through sol–gel method

Potassium tantalate (KT) thin films and powders of both K₂Ta₂O₆ (KT pyrochlore) and KTaO₃ (KT perovskite) structures were prepared by means of chemical solution deposition method using Si(111) with ZnO and MgO buffer layers as a substrate. The influence of reaction atmosphere on reaction pathway and phase composition for both KT powders, and KT thin films has been studied mainly by means of powder diffraction and infrared spectroscopy. When an oxygen flow instead of static air atmosphere has been used the process of pyrolysis in oxygen runs over much narrower temperature interval (200–300 °C), relatively to air atmosphere (200–600 °C) and almost no (in case of powders), or no (in case of thin films) pyrochlore intermediate phase has been detected in comparison with treatment in air, where the pyrochlore phase is stable at temperatures 500–600 °C (powders). KT perovskite phase starts to crystallize at temperatures 50° and 150 °C lower compared to air atmosphere in case of powders and thin films, respectively. Microstructure formed by near-columnar grains and small grains of equiaxed shape was observed in films treated in oxygen and air atmosphere, respectively.     

HCB11(CF3)(n)F(11-n)-: inert anions with high anodic oxidation potentials

Cs salts of four of the title anions were prepared by fluorination of salts of partly methylated (n = 11, 10) or partly methylated and partly iodinated (n = 6, 5) CB(11)H(12)(-) anions. The CH vertex is acidic, and in the unhindered anion with n = 6 it has been alkylated. Neat Cs(+)[1-H-CB(11)(CF(3))(11)](-) is as treacherously explosive as Cs(+)[CB(11)(CF(3))(12)](-), but no explosions occurred with the salts of the other three anions. BL3YP/6-31G* gas-phase electron detachment energies of the title anions are remarkably high, 5-8 eV. Treated with NiF(3)(+) in anhydrous liquid HF at -60 °C, anions with n = 11 or 10 resist oxidation, whereas anions with n = 6 or 5 are converted to colored EPR-active species, presumably the neutral radicals [HCB(11)(CF(3))(n)F(11-n)](?). These are stable for hours at -60 °C after extraction into cold perfluorohexane or perfluorotri-n-butylamine solutions. On warming to -20 °C in a Teflon or quartz tube, the color and EPR activity disappear, and the original anions are recovered nearly quantitatively, suggesting that the radicals oxidize the solvent.     

Formation of two isomeric closo-[(eta5-C5H5)FePC2B8H10] phosphadicarbaborane analogues of ferrocene via isolable eta1-bonded complexes of the [7-[(eta5-C5H5)Fe(CO)2]-(eta1-nido-PC2B8H10)] type

The reaction of nido-[7,8,9-PC(2)B(8)H(11)] (1) with [[CpFe(CO)(2)](2)] (Cp=eta(5)-C(5)H(5) (-)) in benzene (reflux, 3 days) gave an eta(1)-bonded complex [7-Fp-(eta(1)-nido-7,8,9,-PC(2)B(8)H(10))] (2; Fp=CpFe(CO)(2); yield 38 %). A similar reaction at elevated temperatures (xylene, reflux 24 h) gave the isomeric complex [7-Fp-(eta(1)-nido-7,9,10-PC(2)B(8)H(10))] (3; yield 28 %) together with the fully sandwiched complexes [1-Cp-closo-1,2,4,5-FePC(2)B(8)H(10)] 4 a (yield 30%) and [1-Cp-closo-1,2,4,8-FePC(2)B(8)H(10)] 4 b (yield 5%). Compounds 2 and 3 are isolable intermediates along the full eta(5)-complexation pathway of the phosphadicarbaborane cage; their heating (xylene, reflux, 24 h) leads finally to the isolation of compounds 4 a (yields 46 and 52%, respectively) and 4 b (yields 4 and 5%, respectively). Moreover, compound 3 is isolated as a side product from the heating of 2 (yield 10%). The structure of compound 4 a was determined by an X-ray structural analysis and the constitution of all compounds is consistent with the results of mass spectrometry and IR spectroscopy. Multinuclear ((1)H, (11)B, (31)P, and (13)C), two-dimensional [(11)B-(11)B]-COSY, and (1)H[(11)B(selective)] magnetic resonance measurements led to complete assignments of all resonances and are in excellent agreement with the structures proposed.     

Die Bestimmung des Fluors im Fluorit nach Jannasch's Methode

Ohne Zusammenfassung     

Eine schnelle Methode zur Bestimmung von Jodid in Anwesenheit von Chlorid und Bromid

Zusammenfassung Auf Grund der Gleichung: 3 ClO^– + J^–=3 Cl^– + JO₃ ^– wurde eine schnelle Methode zur Bestimmung von Jodid ausgearbeitet, die wie folgt ausgeführt wird: Die 10–40 mg Jodid-Jod enthaltende Lösung wird mit etwa 0,2 g KBr, ferner mit 1,9 g H₃BO₃ oder 2,3 g KHCO₃ versetzt, mit wenig dest. Wasser verdünnt und auf eine Temperatur von annÄhernd 50–60 C erwÄrmt. Man gibt jetzt eine überschüssige, 25 ml Thiosulfatlösung Äquivalente Menge von 0,1 n NaOCl-Lösung zu und bringt die etwas abgekühlte Lösung über freier Flamme in 4–5 sec wieder auf 50–60 C. Nach 1–1,5 minutigem Stehen setzt man 10 ml 30%ige Natronlauge und 25 ml 0,1 n Na₂S₂O₃-Lösung (die der verwendeten NaOCl-Lösung Äquivalent sind) zu und titriert mit 0,1 n NaOCl-Lösung unter Anwendung von je 1 Tr. 1%iger alkoholischer Brasilinlösung als Indicator und 1 Tr. 5%iger KJ-Lösung als Katalysator, bis die Farbe der Lösung von rosa nach gelblichgrün umschlÄgt. Die Methode ist auch in Anwesenheit von Chlorid und Bromid anwendbar, wobei besser KHCO₃ statt BorsÄure zugesetzt wird. Wird bei der Bestimmung H₃BO₃ verwendet, so kann die zum Endpunkt titrierte Lösung — nach Zugabe von 1–2 g KJ und nach AnsÄuern mit wenig 20%iger SchwefelsÄure — in saurem Medium mit 0,1 n Na₂S₂O₃-Lösung weiter titriert werden. Auf diese Art kann der Jodidgehalt in einer einzigen Probe bestimmt und auch kontrolliert werden.Ich fühle mich verpflichtet, Herrn Professor Dr. Johann Proszt, dem Leiter des Institutes, meinen aufrichtigsten Dank auch an dieser Stelle auszusprechen für die Liebenswürdigkeit, womit er meine Versuche ermöglicht hat.     

Jodometrische Bestimmung von Antimon in Erzen

Zusammenfassung In komplizierten Erzmaterialien wird Antimon mit Hilfe des Freiberger Aufschlusses in Lösung gebracht und von vielen Begleitelementen getrennt. Die Sulfosalze werden mit Wasserstoffperoxid oxydiert und Sb^v danach mit Sulfit zu Sb^III reduziert. Nach Zugabe von Weinsäure und ÄDTA wird Sb bei p_H 9 mit Natriumdiäthyldithiocarbamidat gefällt und mit Chloroform extrahiert. Aus der organischen Phase wird Antimon(III) mit Cadmium verdrängt, rückextrahiert und in der wäßrigen Phase mit einer Jod-Maßlösung titriert.

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Summary For the determination of antimony in complicated ores the sample is fused with potassium carbonate and sulphur. In this way a separation from many accompanying elements is achieved. The thiosalts are oxidized by hydrogen peroxide, whereupon antimony is reduced from the quin quevalent to the trivalent state by means of sodium sulphite. After addition of tartaric acid and EDTA antimony is precipitated at p_H 9 with sodium diethyldithiocarbamidate and extracted with chloroform. From the organic phase antimony is reextracted by displacement with cadmium salt and titrated with a standard iodine solution.

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Ein ähnliches Verfahren zur Zinkbestimmung vgl. Jankvoský, J.: diese Z. 201, 330 (1964).     

Field-flow fractionation in microfluidic channels of low aspect ratio

The shape of the steady-state three-dimensional flow velocity profile established in carrier liquid flowing inside the rectangular cross-sectional channel for field-flow fractionation should be taken into account to optimize the separation. The central parts of this profile in the planes parallel to the main channel walls are flat with almost identical flow velocities which drop down to zero at the side walls. The separated species transported by the flow in the close-to-side walls regions move with lower average velocities compared to the species transported in the central part of the channel and are undesirably broadened. The hydrodynamic splitting of the carrier liquid at the entry of the channel where the sample is injected only into the central part of the channel eliminates the excessive zone broadening. The aspect ratio of the breadth to the thickness of the channel ratio can thus be reduced. The effect of various aspect ratios on the shape of the flow velocity profile is calculated and the results are used to optimize the aspect ratio of microfluidic channels. The experiments carried out by microthermal field-flow fractionation confirmed that the aspect ratio cannot be reduced to a value of 1, proposed by other authors.     

Silyl‐Phosphino‐Carbene Complexes of Uranium(IV)

Unprecedented silyl‐phosphino‐carbene complexes of uranium(IV) are presented, where before all covalent actinide–carbon double bonds were stabilised by phosphorus(V) substituents or restricted to matrix isolation experiments. Conversion of [U(BIPM^TMS)(Cl)(μ‐Cl)₂Li(THF)₂] ( 1 , BIPM^TMS=C(PPh₂NSiMe₃)₂) into [U(BIPM^TMS)(Cl){CH(Ph)(SiMe₃)}] ( 2 ), and addition of [Li{CH(SiMe₃)(PPh₂)}(THF)]/Me₂NCH₂CH₂NMe₂ (TMEDA) gave [U{C(SiMe₃)(PPh₂)}(BIPM^TMS)(μ‐Cl)Li(TMEDA)(μ‐TMEDA)_0.5]₂ ( 3 ) by α‐hydrogen abstraction. Addition of 2,2,2‐cryptand or two equivalents of 4‐N,N‐dimethylaminopyridine (DMAP) to 3 gave [U{C(SiMe₃)(PPh₂)}(BIPM^TMS)(Cl)][Li(2,2,2‐cryptand)] ( 4 ) or [U{C(SiMe₃)(PPh₂)}(BIPM^TMS)(DMAP)₂] ( 5 ). The characterisation data for 3 – 5 suggest that whilst there is evidence for 3‐centre P?C?U π‐bonding character, the U=C double bond component is dominant in each case. These U=C bonds are the closest to a true uranium alkylidene yet outside of matrix isolation experiments.     

Analysis of the IGLO bond contributions to the 13C shielding tensors in the local bond frame

A new method is presented to analyze the IGLO (individual gauge for localized orbitals) bond contributions in ¹³C chemical shielding. The IGLO bond contributions calculated in the molecular frame are rotated to a local bond frame, in which one component is selected along the bond. This procedure removes the explicit angular dependence of the IGLO bond contributions and allows a comparison of the bond contributions in different molecules. The results provide a new method to study the electronic basis of shielding interactions. The problems associated with the multiple gauge origins used in the IGLO method are discussed in their relationship to the bond contribution analysis.