Zur Kenntnis des Verhaltens der Oxidsulfate der Seltenen Erden gegen Chlorwasserstoff. II. Charakterisierung und thermisches Verhalten der Umsetzungsprodukte der Oxidsulfate mit Chlorwasserstoff

The reaction products of the oxide sulphates of rare earths with hydrogen chloride are mixtures of chlorides M^IIICl₃ and chloride-sulphates M^IIICl₃ and chloride-sulphates M^IIIClSO₄. By oxidation of these mixtures, oxide sulphates MO₂SO₄ are formed as final products. Intermediary products are mixtures of M^IIIOCl? M^IIIClSO₄.     

Zur Kenntnis des Verhaltens der Oxidsulfate der Seltenen Erden gegen Chlorwasserstoff. III. Darstellung und thermisches Verhalten der Chloridsulfate der Seltenen Erden

Treatment of chlorination products of rare earths oxidesulphates with methanol yields chloride-sulphates M^IIIClSO₄ as residues. Thermal decomposition of chloride-sulphates yields oxide-sulphates MO₂SO₄; as intermediates, mixtures of the composition MO₂SO₄? M(SO₄)₃ are obtained.     

Chemische Reaktionen in Salzschmelzen. XX. Zur elektrochemischen Wiedergewinnung von Chlor aus Chlorwasserstoff

Chemical Reactions in Molten Salts. XX. Electrochemical Recycling of Chlorine from Hydrogenchloride A continuously working process for splitting up waste hydrogenchloride yielding chlorine and hydrogen is described. Hydrogenchloride is reduced by reactive metals or low-valent metal ions in a molten salt bath forming hydrogen. The resulting metal chloride dissolves in the melt and is electrolized to chlorine and the previous metal. Among the investigated systems most appropriate are Cd/CdCl₂? NaCl, Zn/ZnCl₂? KCl and Al/NaAlCl₄, respectively, which proceed with suspensions of a solid metal or utilizing the solubility of the metal. – The use of a diaphragm permits to construct the cathode chamber as a bubble column or agitator vessel. The process is comparable with the electrolysis of hydrochloric acid with respect to energy consumption, purity of products and volume-time-yields (RZA).     

Darstellung intramolekular stabilisierter Diazaphosphorinan-Derivate mit der Trimethylethylendiamin- bzw. der Tetramethylguanidingruppe als Substituent am Phosphor: Studium intramolekularer Me2N → P-Wechselwirkungen

Formation of Intramolecularly Stabilized Diazaphosphorinane Derivatives with the Trimethylethylenediamine and the Tetramethylguanidine Group as Substituents at Phosphorus: Investigation of intramolecular Me₂N → P Interactions In the reaction of trimethylchlorophosphonium chloride 1 with N-trimethylsilyl-N′,N′,N″,N″-tetramethylguanidine 2 the expected guanidine-substituted trimethylphosphonium chloride 3 was formed, presumably via the ammonium chloride 3a which could not be isolated. By contrast, the reaction of the related chloromethyldimethylchlorophosphonium chloride 5 with N-trimethylsilyl-N,N′,N′-trimethylethylenediamine 6 and N-trimethylsilyl-N′,N′-dimethylethylene diamine, 7 , respectively, furnished in an unusual fashion six-membered heterocycles, the ammonium-phosphonium dichlorides 10 and 11 . Their formation involved cleavage of both the P? Cl and the C? Cl bond, followed by intramolecular C←N-acceptor-donor interaction. A similar C←N interaction was not observed in the reaction of 5 with 2 , and the acyclic product 12 was formed. The reaction of chloromethylmethylchlorophosphine 13 with the hydrogen peroxide/urea 1:1-adduct led to chloromethylmethylphosphinic acid 14 . Attempts at the reaction of 14 with 2 or with SOCl₂ were unsuccessful. The reaction products were characterized by ¹H-, ¹³C-, ³¹P- and, in two cases, by ¹⁵N-NMR-spectroscopy.     

Zur Kinetik der Kontakteliminierung von Chlorwasserstoff aus Äthylchlorid im Strömungsreaktor

Zusammenfassung Mit einer Strömungsapparatur wurde die Kinetik der katalytischen Eliminierung C₂H₅ClC₂H₄+HCl an MgSO₄ und Al₂O₃ zwischen 280 und 430°C und bei Drucken zwischen 2 und 35 Torr mit Helium als Trägergas untersucht. Störungen durch Diffusion sowie die Rückreaktion wurden dabei weitgehend ausgeschaltet.Durch Variation der Verweilzeit bei konstantem Anfangsdruck kann gezeigt werden, daß die Reaktion über den ganzen Umsatz nach erster Ordnung verläuft. Die Geschwindigkeitskonstante nimmt jedoch mit steigendem Anfangsdruck ab. Vorliegen einer Adsorption vomLangmuirtyp erklärt dieses Verhalten.Die spezifische Aktivität von MgSO₄ (Aktivierungsenergie 28 kcal/Mol) ist rund 1000mal höher als die von Al₂O₃ (Aktievierungsenergie 21 kcal/Mol), was durch den höheren Häufigkeitsfaktor von MgSO₄ bedingt ist.

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Kinetics of the catalytic dehydrochlorination of ethyl chloride in a flow reactor

The kinetics of the catalytic elimination C₂H₅ClC₂H₄+ +HCl over MgSO₄ and Al₂O₃ was studied at pressures between 2 and 35 torr and in the temperature range 280° to 430° C. A flow apparatus was used with He as carrier gas. Influences of diffusion and back reaction were avoided. At a given initial pressure the reaction obeys a first order kinetic law over the whole conversion. However, the rate constant decreases with increasing initial pressure. This is interpreted with aLangmuir type adsorption. The specific activity of MgSO₄ (activation energy 28 kcal/mol) is roughly 1000 times higher than that of Al₂O₃ (activation energy 21 kcal/mol). This is due to a higher frequency factor of MgSO₄.

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Mit 8 Abbildungen

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Herrn Prof. Dr.H. Nowotny gewidmet.     

Stereospezifische Synthese und Isomerisierung der 10-Chlor-decahydroisochinoline. Decahydroisochinoline. IV. Teil

Treatment of cis- and trans-10-hydroxy-N-methyl-decahydroisoquinoline, ( 3a ) and ( 10a ) respectively, or N-methyl-Δ^9,10-octahydroisoquinoline ( 4 a ) with hydrogen chloride in acetic acid affords the thermodynamically more stable trans-isomer of 10-chloro-N-methyl-decahydroisoquinoline ( 1a ). On the other hand ring closure of β-(cyclohexen-1-yl)-ethylamines 11a or 11b with aqueous formaldehyde in the presence of chloride ions leads to the 10-cis-chlorides 2a or 2b in a kinetically controlled reactions.     

Bis(5‐tert‐butyl‐2‐hydroxy‐3‐methylbenzyl)(6‐hydroxyhexyl)ammonium chloride monohydrate,an anion receptor complex

In the title compound, C₃₀H₄₈NO₃⁺·Cl⁻·H₂O, the cation acts with a water molecule as a chloride ion receptor. The chloride ion forms three strong intramolecular hydrogen bonds. The water molecule forms both an intramolecular bridge between one phenol H atom and the chloride ion, and an intermolecular link to the aliphatic alcohol O atom. Weak intermolecular C—H...Cl and C—H ...O hydrogen bonds provide additional packing interactions.     

Hydrogen bonding: Part 19. IR and NMR study of the lower hydrates of choline fluoride and acetylcholine chloride

Acetylcholine chloride, like choline chloride, forms a liquid salt dihydrate, and a crystalline monohydrate that only exists at reduced pressure; at atmospheric pressure the monohydrate disproportionates into liquid dihydrate and anhydrous acetylcholine chloride. Both choline and acetylcholine chlorides give endothermic dissolution in water. In contrast, choline fluoride gives exothermic dissclution in water, and forms an extra-ordinarily stable monohydrate in which choline cation hydroxyls form strong hydrogen bonds to an H₄O₂F^2?₂ cluster anion. Since the hydration behavior of choline fluoride is like that of unsubstituted tetraalkylammonium fluorides, the unusual hydration behavior of choline and acetyline chlorides results from the presence of chloride ion, and is not an intrinsic property of cholinergic cations.     

The anilinium chloride adduct of 4‐bromo‐N‐phenylbenzene­sulfonamide

The title compound anilinium chloride–4‐bromo‐N‐phenyl­benzene­sulfonamide (1/1), C₆H₈N⁺·Cl⁻·C₁₂H₁₀BrNO₂S, displays a hydrogen‐bonded ladder motif with four independent N—H⋯Cl bonds in which both the NH group of the sulfonamide molecule and the NH₃ group of the anilinium ion [N⋯Cl = 3.135 (3)–3.196 (2) Å and N—H⋯Cl = 151–167°] are involved. This hydrogen‐bonded chain contains two independent R₄²(8) rings and each chloride ion acts as an acceptor of four hydrogen bonds.     

Melaminium chloride hemihydrate

The crystals of a new melaminium salt, 2,4,6‐tri­amino‐1,3,5‐triazin‐1‐ium chloride hemihydrate, C₃H₇N₆⁺·Cl^?·0.5H₂O, are built up from single‐protonated melaminium residues, chloride anions and water mol­ecules. The protonated melaminium cations lie on a twofold axis, while the chloride anions and water mol­ecule lie on the m plane. The melaminium residues are interconnected by N—H?N hydrogen bonds, forming chains parallel to the (001) plane. The chains of melaminium residues form a three‐dimensional network through hydrogen‐bond interactions with chloride anions and water mol­ecules.     

Spektroskopische Eigenschaften von HCl-Addukten der Di(phthalocyaninato(2–))lanthanidsäuren

Spectroscopic Properties of HCl Adducts of the Di(phthalocyaninato(2–))lanthanide Acids Thin films of bis(triphenylphosphine)iminiumdi(phthalocyaninato(2–))lanthanidates(III), (PNP)[Ln(Pc²)₂] (Ln = La…(? Ce, Pm)…Lu) react with hydrogen chloride yielding the green acid adduct [HLn(Pc^2?)₂] · xHCl. The typical π–π* transitions of the Pc^2? ligand are observed in the UV-VIS spectra (B: ～ 14500 cm^?1; Q: ～ 30300 cm^?1); these are broadened and shifted to lower energy with respect to those of the precursor. A N? H stretching vibration at ～ 3170 cm^?1 as well as a H? N? C deformation vibration at ～ 1200 cm^?1 in the MIR spectra are diagnostic for these HCl adducts.     

Lamotrigine,an antiepileptic drug,and its chloride and nitrate salts

In lamotrigine [systematic name: 6‐(2,3‐dichlorophenyl)‐1,2,4‐triazine‐3,5‐diamine], C₉H₇Cl₂N₅, (I), the asymmetric unit contains one lamotrigine base molecule. In lamotriginium chloride [systematic name: 3,5‐diamino‐6‐(2,3‐dichlorophenyl)‐1,2,4‐triazin‐2‐ium chloride], C₉H₈Cl₂N₅⁺·Cl⁻, (II), the asymmetric unit contains one lamotriginium cation and one chloride anion, while in lamotriginium nitrate, C₉H₈Cl₂N₅⁺·NO₃⁻, (III), the asymmetric unit contains two crystallographically independent lamotriginium cations and two nitrate anions. In all three structures, N—H...N hydrogen bonds form an R₂²(8) dimer. In (I) and (II), hydrophilic layers are sandwiched between hydrophobic layers in the crystal packing. In all three structures, hydrogen bonds lead to the formation of a supramolecular hydrogen‐bonded network. The significance of this study lies in its illustration of the differences between the supramolecular aggregation in the lamotrigine base and in its chloride and nitrate salts.     

Zur kenntnis der cyclopentadienyl-nitrosyl-carbonyl-isonitril-komplexe der VI. Und der cyclopentadienyl-dicarbonyl-isonitril-komplexe der VII. Nebengruppe

The nitrosylcarbonylisonitrile complexes η⁵-C₅H₅M(NO)(CO)CNR (R = Me for Cr, Mo, W; R = Et, SiMe₃, GeMe₃, SnMe₃ for Mo) are formed by treatment of the nitrosylcarbonylcyanometalates Na[η⁵-C₅H₅M(NO)(CO)CN] with [R₃O]BF₄ (R = Me, Et), Me₃SiCl, Me₃GeCl or Me₃SnCl. The isoelectronic dicarbonylisonitrile compounds η⁵-C₅H₅Mn(CO)₂CNR (R = SiMe₃, GeMe₃, SnMe₃, PPh₂, AsMe₂) and η⁵-C₅H₅Re(CO)₂CNAsMe₂ are obtained by analogous reactions of Na[η⁵-C₅H₅M(CO)₂CN] (M = Mn, Re) with Me₃ECl (E = Si, Ge, Sn), Ph₂PCl and Me₂AsBr.With phosgene the anionic complexes Na[η⁵-C₅H₅M(CO)₂CN] (M = Mn, Re) can be transformed into the new carbonyldiisocyanide-bridged dinuclear complexes η⁵-C₅H₅M(CO)₂CN-C(O)-NC(OC)₂M-η⁵-C₅H₅. Finally, the reactions of η⁵-C₅H₅M(NO)(CO)CNMe (M = Cr, Mo, W) with NOPF₆, leading to the cationic dinitrosylisonitrile complexes [η⁵-C₅H₅M(NO)₂CNMe]⁺, are described.     

Hydrogen‐bonding motifs and thermotropic polymorphism in redetermined halide salts of hexamethylenediamine

The redetermined crystal structures of hexane‐1,6‐diammonium dichloride, C₆H₁₈N₂²⁺·2Cl⁻, (I), hexane‐1,6‐diammonium dibromide, C₆H₁₈N₂²⁺·2Br⁻, (II), and hexane‐1,6‐diammonium diiodide, C₆H₁₈N₂²⁺·2I⁻, (III), are described, focusing on their hydrogen‐bonding motifs. The chloride and bromide salts are isomorphous, with both demonstrating a small deviation from planarity [173.89 (10) and 173.0 (2)°, respectively] in the central C—C—C—C torsion angle of the hydrocarbon backbone. The chloride and bromide salts also show marked similarities in their hydrogen‐bonding interactions, with subtle differences evident in the hydrogen‐bond lengths reported. Bifurcated interactions are exhibited between the N‐donor atoms and the halide acceptors in the chloride and bromide salts. The iodide salt is very different in molecular structure, packing and intermolecular interactions. The hydrocarbon chain of the iodide straddles an inversion centre and the ammonium groups on the diammonium cation of the iodide salt are offset from the planar hydrocarbon backbone by a torsion angle of 69.6 (4)°. All three salts exhibit thermotropic polymorphism, as is evident from differential scanning calorimetry analysis and variable‐temperature powder X‐ray diffraction studies.     

Metallboranate und Boranatometallate. 14. Chlorid-tetrahydridoborate des Calciums und Strontiums

Metal Tetrahydridoborates and Tetrahydridoborato Metalates. 14. Chloro Tetrahydridoborates of calcium and Strontium The action of hydrogen chloride on E(BH₄)₂ (E ? Ca, Se) in a 1:1 mole ratio in tetrahydrofuran yields the title compounds isolated as their tetrahydrofuran adducts. No intermediates were detected by ¹¹B n.m.r. spectroscopy in the reaction of methanol with Ca(BH₄)₂. The final product is Ca[B(OCH₃)₄]₂ · THF.     

Aktivierungsenergie und Mechanismus der intramolekularen Wasserstoff-Wanderung bei Radikal-Kationen von Keto/Enol-Tautomeren in der Gasphase

The collisional activation mass spectra prove that non-decomposing ionized methyl acetate [CH₃COOCH₃]⁺? and its enolic isomer [CH₂?C(OH)OCH₃]⁺? exist as stable species in potential wells. It is shown, however, that prior to CH₃O? loss the decomposing [CH₂?C(OH)OCH₃]⁺? ion isomerizes via a rate determining symmetry forbidden [1.3] hydrogen rearrangement to ionized methyl acetate. The alternative mode of two consecutive formally symmetry allowed [1.2] hydrogen migrations can be certainly excluded for this isomerization. The activation energy of such hydrogen rearrangements is of the order of 41–83 kcal · mol^?1 depending on the electronic nature of the cations (“open” or “closed” shell systems).     

Ropinirole hydro­chloride,a dopamine agonist

Ropinirole hydro­chloride, or diethyl[2‐(2‐oxo‐2,3‐dihydro‐1H‐indol‐4‐yl)ethyl]ammonium chloride, C₁₆H₂₅N₂O⁺·Cl⁻, belongs to a class of new non‐ergoline dopamine agonists which bind specifically to D2‐like receptors with a selectivity similar to that of dopamine (D3 > D2 > D4). The N atom in the ethyl­amine side chain is protonated and there is a hydrogen bond between it and the Cl⁻ ion. In the crystal structure, two cations and two anions form inversion‐related cyclic dimers via N—H⋯Cl hydrogen bonds.     

Packing forces in dichloridobis(3,5‐diphenyl‐1H‐pyrazole‐κN2)cobalt(II) dichloromethane hemisolvate

The title compound, [CoCl₂(C₁₅H₁₂N₂)₂]·0.5CH₂Cl₂, was crystallized from a binary mixture of dichloromethane and hexane and a dimeric supramolecular structure was isolated. The Co^II centre exhibits a distorted tetrahedral geometry, with two independent pyrazole‐based ligands occupying two coordination sites and two chloride ligands occupying the third and fourth coordination sites. The supramolecular structure is supported by complementary hydrogen bonding between the pyrazole NH group and the chloride ligand of an adjacent molecule. This hydrogen‐bonding motif yields a ten‐membered hydrogen‐bonded ring. Density functional theory (DFT) simulations at the PBE/6‐311G level of theory were used to probe the solid‐state structure. These simulations suggest that the chelate undergoes a degree of conformational distortion from the lowest‐energy geometry to allow for optimal hydrogen bonding in the solid state.     

Dihaloiodates(I): synthesis with hydrogen peroxide and their halogenating activity

Tetraalkylammonium and pyridinium dichloro- and dibromoiodates(I) were efficiently prepared from iodine and tetralkylammonium chloride or pyridine by oxidation with hydrogen peroxide in the presence of an equimolar amount of a hydrogen halide. Their halogenating activity was tested on 1,3-dimethoxybenzene and styrene as model substrates. The results show that ICl₂^? salts acted as iodinating reagents, while IBr₂^? salts brominated both substrates.