High‐Pressure Synthesis,Crystal Structure,and Properties of GdS2 with Thermodynamic Investigations in the Phase Diagram Gd–S

Gadolinium disulfide was prepared by high‐pressure synthesis at 8 GPa and 1173 K. It crystallizes in the monoclinic space group P12₁/a1 (No. 14) with lattice parameters a = 7.879(1) Å; b = 3.936(1) Å, c = 7.926(1) Å and β = 90.08(1)°. The crystal structure is a twofold superstructure of the aristotype ZrSSi and consists of puckered cationic [GdS]⁺ double slabs that are sandwiched by planar sulfur sheets containing S₂^2– dumbbells. The thermal decomposition of GdS₂ proceeds via the sulfur‐deficient polysulfides GdS_1.9, GdS_1.85 and GdS_1.77 and eventually results in the sesquisulfide Gd₂S₃. GdS₂ is a paramagnetic semiconductor which orders antiferromagnetically at T_N = 7.7(1) K. A metamagnetic transition is observed in the magnetically ordered state.     

Cyclische Thiophosphate,Produkte der Umsetzung von elementarem Phosphor mit Alkylammoniumpolysulfiden

Cyclic Thiophosphates, Products from the Reaction of Elemental Phosphorus with Alkylammonium Polysulfides White Phosphorus reacts very rapidly above its melting point with alkylammonium polysulfide solutions in chloroform or dimethylformamide. The reaction products are mixtures of thiophosphates, which contain compounds with phosphorus in different oxidation states. The composition of these mixtures may be changed by varying the amounts of applied polysulfidic sulfur and alkylamine. Several cyclic thiophosphates have been isolated from the mixtures in good yields; some contain P? P bonds.     

Two-dimensional vermiculite separator for lithium sulfur batteries

A lamellar vermiculite separator assembled with exfoliation vermiculites is developed for lithium sulfur batteries. The vermiculite separator can simultaneously suppress the parasitic reactions induced by polysulfide intermediate shuttle, and prevent the short circuit by potential lithium dendrite penetration with the ultrahigh Young's modulus.     

Methylene blue derivatization then LC–MS analysis for measurement of trace levels of sulfide in aquatic samples

The methylene blue method has been widely used for analysis of sulfide for more than 100 years. Direct measurement of methylene blue at nanomolar concentrations is impossible without a preconcentration step, however. In this study the response of LC–MS with electrospray ionization (ESI) to methylene blue was evaluated. HPLC with simple isocratic elution was followed by ESI-MS quantification, which was compared with traditional UV–visible detection. The limit of detection for sulfide was approximately 50 ng L⁻¹, or 1.5 nmol L⁻¹. Analysis time was substantially reduced by use of isocratic elution. Interfering compounds produced by side reactions can be eliminated by use of the mass filter. A polysulfide sample was also analyzed to determine which products are formed and whether or not polysulfides react stoichiometrically with methylene blue reagent. It seems that polysulfides do not react quantitatively with methylene blue and so cannot be quantified reliably by use of this method.     

Higher-order polysulfides induced thermal runaway for 1.0 Ah lithium sulfur pouch cells

Comprehensive analyses on thermal runaway mechanisms are critically vital to achieve the safe lithium–sulfur (Li–S) batteries. The reactions between dissolved higher-order polysulfides and Li metal were found to be the origins for the thermal runaway of 1.0 Ah cycled Li–S pouch cells. 16-cycle pouch cell indicates high safety, heating from 30 to 300 °C without thermal runaway, while 16-cycle pouch cell with additional electrolyte undergoes severe thermal runaway at 147.9 °C, demonstrating the key roles of the electrolyte on the thermal safety of batteries. On the contrary, thermal runaway does not occur for 45-cycle pouch cell despite the addition of the electrolyte. It is found that the higher-order polysulfides (Li₂S_x ≥ 6) are discovered in 16-cycle electrolyte while the sulfur species in 45-cycle electrolyte are Li₂S_x ≤ 4. In addition, strong exothermic reactions are discovered between cycled Li and dissolved higher-order polysulfide (Li₂S₆ and Li₂S₈) at 153.0 °C, driving the thermal runaway of cycled Li–S pouch cells. This work uncovers the potential safety risks of Li–S batteries and negative roles of the polysulfide shuttle for Li–S batteries from the safety view.     

Darstellung,Eigenschaften, röntgenographische und spektroskopische Untersuchung von Tl4Nb2S11 und Tl4Ta2S11

On Polychalcogenides of Thallium with M₂Q₁₁ Groups as a Structural Building Block. I Preparation, Properties, X‐ray Diffractometry, and Spectroscopic Investigations of Tl₄Nb₂S₁₁ and Tl₄Ta₂S₁₁ The new ternary compounds Tl₄Nb₂S₁₁ and Tl₄Ta₂S₁₁ were prepared using Thallium polysulfide melts. Tl₄M₂S₁₁ crystallises isotypically to K₄Nb₂S_8.9Se_2.1 in the triclinic space group P 1 with a = 7.806(2) Å, b = 8.866(2) Å, c = 13.121(3) Å, α = 72.72(2)°, β = 88.80(3)°, and γ = 85.86(2)° for M = Nb and a = 7.837(1) Å, b = 8.902(1) Å, c = 13.176(1) Å, α = 72.69(1)°, β = 88.74(1)°, and γ = 85.67(1)° for M = Ta. The interatomic distances as well as angles within the [M₂S₁₁]^4– anions are similar to those of the previously reported data for analogous alkali metal polysulfides. Significant differences between Tl₄M₂S₁₁ and A₄M₂S₁₁ (A = K, Rb, Cs) are obvious for the shape of the polyhedra around the electropositive elements. The two title compounds melt congruently at 732 K (M = Nb) and 729 K (M = Ta). The optical band gaps were estimated as 1.26 eV for Tl₄Nb₂S₁₁ and as 1.80 eV for the Tantalum compound.     

Synthesis and Crystal Structures of New Antimony Polysulfido Complexes: [P(C6H5)4]3Sb3S25 and [P(C6H5)4]2Sb2S15 · 2(C3N2H6)

Reaction of elemental antimony with sulfur under mild hydrothermal conditions yielded different polysulfido-clusters of antimony. These were isolated as tetraphenylphosphonium salts [P(C₆H₅)₄]₃Sb₃S₂₅ and [P(C₆H₅)₄]₂Sb₂S₁₅ · 2(C₃N₂H₆) and their crystal structures were determined. In the first compound two different polysulfide anions are observed, Sb₂S₁₇^2– and Sb₂S₁₆^2–, whereas the second contains the Sb₂S₁₅^2– complex. These dinuclear anions show as a common building principle two ψ-trigonal bipyramidal coordinated Sb centers bridged by two S_x^2– units and an additional S_x^2– chelate ligand bound to each Sb center giving a tricyclic structure.     

Remote Control of the Synthesis of a [2]Rotaxane and its Shuttling via Metal-Ion Translocation

Remote control in an eight-component network commanded both the synthesis and shuttling of a [2]rotaxane via metal-ion translocation, the latter being easily monitored by distinct colorimetric and fluorimetric signals. Addition of zinc(II) ions to the red colored copper-ion relay station rapidly liberated copper(I) ions and afforded the corresponding zinc complex that was visualized by a bright sky blue fluorescence at 460 nm. In a mixture of all eight components of the network, the liberated copper(I) ions were translocated to a macrocycle that catalyzed formation of a rotaxane by a double-click reaction of acetylenic and diazide compounds. The shuttling frequency in the copper-loaded [2]rotaxane was determined to k₂₉₈=30 kHz (ΔH^≠=62.3±0.6 kJ mol⁻¹, ΔS^≠=50.1±5.1 J mol⁻¹ K⁻¹, ΔG^≠₂₉₈=47.4 kJ mol⁻¹). Removal of zinc(II) ions from the mixture reversed the system back generating the metal-free rotaxane. Further alternate addition and removal of Zn²⁺ reversibly controlled the shuttling mode of the rotaxane in this eight-component network where the ion translocation status was monitored by the naked eye.     

Electrospray Ionization Mass Spectrometric Analysis of Aqueous Polysulfide Solutions

The speciation of polysulfides in aqueous solutions was investigated by electrospray – ion trap and electrospray – time of flight mass spectrometry. The pH dependence of the observed total dissolved polysulfides concentration followed the trend calculated based on reported thermodynamic constants. However, the observed species distributions were substantially different from those calculated based on thermodynamic coefficients derived by UV spectroscopy. Notably, large abundances of heptasulfide, octasulfide and nonasulfide species were observed throughout the pH range 6 to 11. The large molecular weight anions had not been reported before in aqueous solutions although indirect evidence had suggested their existence.