RESUMEN
Aqueous solutions of lithium chloride are an excellent model system for studying the dynamics of water molecules down to low temperatures without freezing. The apparent dynamic crossover observed in an aqueous solution of LiCl at about 220 to 225 K [Mamontov, JPCB 2009, 113, 14073] is located practically at the same temperature as the crossover found for pure water confined in small hydrophilic pores. This finding suggests a strong similarity of water behavior in these two types of systems. At the same time, studies of solutions allow more effective explorations of the long-range diffusion dynamics, because the water molecules are not confined inside an impenetrable matrix. In contrast to the earlier incoherent quasielastic neutron scattering results obtained for the scattering momentum transfers of 0.3 Å(-1) ≤ Q ≤ 0.9 Å(-1), our present incoherent neutron spin-echo measurements at a lower Q of 0.1 Å(-1) exhibit no apparent crossover in the relaxation times down to 200 K. At the same time, our present nuclear magnetic resonance measurements of the diffusion coefficients clearly show a deviation at the lower temperatures from the non-Arrhenius law obtained at the higher temperatures. Our results are consistent with a scenario in which more than one relaxational component may exist below the temperature of the dynamic crossover in water.
RESUMEN
This solid state 13C NMR study confirms, for coals, and extends, for air-oxidized coals, the claim that the Bishop and Ward strong aqueous-acid coal demineralization procedure [M. Bishop, D.L. Ward, Fuel 37 (1958) 191.] does not lead to the formation of detectable levels of cross-links in the organic matrix of these materials. The study was prompted by the demonstration that polymerization accompanies strong acid demineralization in lignin, and the recognition that the chemical environment created in air-oxidized coals contains introduced reactive functionality similar to that in the lignin. In particular, both contain oxidized benzylic carbon functionality that can undergo acid-catalyzed polymerization reactions. For two coals of differing rank, no acid-induced cross-link formation has been observed in the pristine or air-oxidized coals, within the 5 parts per thousand (ppt) sensitivity of the NMR technique used in this study.
Asunto(s)
Carbón Mineral , Aire , Espectroscopía de Resonancia Magnética , Oxidación-ReducciónRESUMEN
A new chemical/spectroscopic couple that differentiates aromatic from aliphatic carboxylic acid polymers was developed. The method is complementary to more traditional methods of identification (IR) and is applicable to the analysis of complex mixtures where IR determinations are complicated by extensive vibrational band overlap. The method entails (1) conversion of carboxylic acids into acid fluorides and (2) specific detection of the resonances of the acid fluoride carbon and of the carbon directly attached to the carbonyl carbon by solid state (19)F-(13)C cross polarization (CP)/MAS (13)C NMR. The assignment of the chemical shift of the latter resonance to either the sp(2) or sp(3) carbon resonance manifold specifies the nature of the acid functionality. The preparation of the acid fluoride derivatives of several polymers containing aliphatic and aromatic carboxylic acid functionality was evaluated using sulfur tetrafluoride (SF(4)), diethylaminosulfur trifluoride (DAST), cyanuric fluoride, and thionyl fluoride. Room temperature reactions using DAST in methylene chloride or neat SF(4) gave the acid fluorides in yields ≥90% for the acids studied. Aromatic acid fluoride yields were essentially quantitative. Aliphatic acid fluorides were contaminated with the anhydride of the acid. The acid fluoride polymers were characterized by solid state (13)C and (19)F MAS/NMR.