Carbon-13 NMR spectra of retinal1 and its related compounds

Carbon-13 NMR spectra of all-trans retinal₁ and vitamin A₁ were measured by the pulse Fourier transform method in CCl₄. All peaks in these spectra were assigned from considerations of chemical shifts, half proton-decoupled spectra, spin-lattice relaxation times and induced chemical shift by the addition of shift reagent. The carbon-13 NMR spectrum was also measured for all-trans retinal₁ which had been exposed to the sunlight for three hours, and the induced isomer was proposed to be 11-s-cis retinal₁.     

环状聚芳酯低聚物的核磁共振谱峰的归属

本文报道了环状聚芳酯低聚物的核磁共振碳谱及氢谱。测定了其碳及氢的自旋晶格驰豫时间，通过与类似物质标准谱图的比较、自旋晶格驰豫时间的分析以及化学位移取代基效应的计算等，归属了其碳氢谱峰。     

The effect of iodine on the carbon-13 relaxation times of pyridine

The addition of iodine to pyridine not only causes appreciable changes in the ¹³C chemical shifts but also a marked reduction in spin-lattice relaxation times. The effect at the γ-carbon is larger than at the α- and β-carbons. This is consistent with the formation of a pyridine-iodine complex with a preferential tumbling about the C-γ? N? I axis. Elementary theory is applied to approximate the tumbling ratio.     

Acceleration of carbon-13 spin-lattice relaxation times in amino acids by electrolytes

Measurements of the enhancement, by various electrolytes, of the spin-lattice relaxation time of carbon-13 at different locations in a number of amino acids are reported. Spin-lattice relaxation times T1 of all the carbons in amino acids generally tend to decrease with increase in the concentration of electrolytes, the largest effects often being observed for the charged carboxylate groups of the amino acids. Carboxylic carbons in amino acids are the sensitive 'acceptor' of the 13C spin-lattice relaxation accelerating effects offered by electrolytes, and the 13C spin-lattice relaxation accelerating ability of electrolytes decreases in the order Mg(ClO4)2 > MgCl2 > CaCl2 > NaCl > KCl > LiClO4 > NaOH. The mechanisms of the observed phenomena are discussed in terms of intermolecular interaction, paramagnetic impurities in electrolytes and other mechanisms; large contributions of intermolecular interactions with electrolytes are present on complex formation between amino acids and metal ions and the incoming 'unsaturation' of the primary solvation shell of cations with the increase in electrolyte concentration.     

High-Resolution Solid-State NMR Characterization of Morphology in Annealed Polylactic Acid

Single-pulse ¹³C NMR spectra and spin-lattice relaxation times T₁(¹H), detected indirectly via ¹³C carbons, and T₁(¹³C) were measured at 31°C for virgin pelletized and annealed polylactic acid (PLA) samples using the magic-angle spinning technique. The structural relaxation resulting in more regular crystals with narrower conformation distribution and increase in the lamellae thickness and crystallinity brought about by annealing at 100°C was deduced from the narrowing of the ¹³C NMR lines and proton spin-lattice relaxation times T₁(¹H). The spin-lattice relaxation times T₁(¹³C) related to the respective carbons of the α-polymorph of PLA are also discussed in the study.     

Silicon-29 and carbon-13 NMR studies of organosilicon chemistry. II—The Methylethoxysilanes MenSi(OEt)4−n

Silicon-29, carbon-13 and oxygen-17 NMR data are reported for the methylethoxysilanes, Me_nSi(OEt)_4?n with n = C to 3. The values of ¹J(SiC) vary greatly, in a manner which appears to be inconsistent with an effect of s-character variation alone. The chemical shifts are discussed in terms of possible π-bonding. Silicon-29 and carbon-13 spin-lattice relaxation times and nuclear Overhauser effects are also reported and discussed.     

13C, 13C coupling constants in phenyl substituted ethylene,naphthalene, phenanthrene and cyclopentadienone. Dependence on dihedral angles. Determination of signs by the symmetrical double labelling (SDL) method. IV

Carbon-13, carbon-13 coupling constants and carbon-13 chemical shifts have been measured in a series of phenyl substituted ethylenes and aromatics all doubly labelled with ¹³C at the olefinic positions (α,β-) or at neighbouring aromatic positions, tetraphenylcyclopentadienone labelled at the 3,4-positions, and dichlorodiphenylmethane labelled at the α-carbon. Signs of coupling constants were determined by the symmetrical double labelling (SDL) method. Coupling constants over as many as five bonds are reported. Two-bond couplings between carbons in the aromatic skeleton belong to different classes according to the nature of the coupling path. The magnitudes of three-bond coupling constants between such carbons correlate linearly with π-bond orders and a separation of the δ- and π-contributions is evident. The three-bond couplings between the 2-position in a phenyl substituent and the olefinic β-position or a corresponding aromatic position depend on the out-of-plane twist of the phenyl ring and may lead to information about the twist angle. Contrary to findings with aromatic carbonyl compounds two- and three-bond couplings to the α-carbon in the present compounds are fairly constant. The reported data suggest that the signs of coupling constants over more than two bonds alternate in aromatic systems. Carbon-13, carbon-13 coupling constants in naphthalene have been calculated by the INDO-SOS method.     

Carbon-13 NMR of polyethylenes: Correlation of the crystalline component T1 with structure

The carbon-13 spin-lattice relaxation times T₁ of the crystalline portion of a set of polyethylenes have been studied. Chain structure and crystallization conditions have been varied over the widest possible extremes so that large differences are developed in the level of crystallinity, the supermolecular structure, and the crystallite thickness. Concomitantly, the observed crystalline T₁ values cover the extraordinarily wide range of about 40–4500 s. They bear a one-to-one relation with the crystallite thickness, which is found to be the key structural variable determining this property. A correlation with the temperature for the α-transition can be established, which implies a similar type of segmental motions for the two phenomena. Major changes in the interfacial structure can also have a drastic influence on the value for the crystalline T₁. Analysis of the magnetization decay curve also allows for a quantitative determination of the degree of crystallinity, which is found to be in excellent agreement with the corresponding value found from Raman spectroscopy.     

13C NMR studies on radical anions. Special solvent effects

The determination of radical ions is crucial in mechanistic studies of reactions in which single electron transfer is suspected. A ¹³C NMR method based on the interaction of radical anions with tetrahydrofuran (THF) molecules is presented; measurements of the broadening of the THF α-carbon signal allow determination of the substrate concentration in the range 0.2–1.2 M . The spectacular effect observed on addition of small amounts of benzene greatly improved the method. In addition, studies of the spin-lattice, T₁, and of the transverse nuclear, T₂, relaxation times and of the effects of added co-solvents allow the proposal of the bonding situation and of the degree of coordination in the radical anion-cation-THF molecules' complex.     

A carbon-13 study of relaxation in the mesophases of 5O·7 and the 5CB homologous series

Abstract

Carbon-13 spin-lattice relaxation times of the protonated ring carbons have been measured at 22·6 MHz in the nematic and all four smectic phases of 5O·7 (4-n-pentyloxybenzylidene-4′-n-heptylaniline). Dong has obtained the deuterium spectral densities J ₁ and J ₂ at 15·4MHz for the deuterated aniline ring of 5O·7-d ₄, and has presented and applied a theory in which the spectral densities are expressed in terms of the diffusion constants D∥ and D?. His results are used to calculate ¹³C relaxation times from the spectral densities J ₀, J ₁ and J ₂. The calculated ¹³C spin-lattice relaxation times are then compared with our experimental values to test the theory. The ¹³C spin-lattice relaxation times of all the resolved resonances in the various phases of the first four members of the 5CB homologous series have been published previously. Dong has also published an analysis of 5CB deuterium data, and we use his results for the diffusion constants D∥ and D? to calculate ¹³C relaxation times of the protonated aromatic carbons of 5CB, 6CB, 7CB and 8CB. The ¹³C relaxation times of the unprotonated aromatic carbons of the 5CB series are calculated in the manner of Wittebort et al., but using the spectral density expressions developed by Dong. The calculated ¹³C spin-lattice relaxation times of the 5CB homologous series are then compared with our experimental values to test the theory for the protonated and unprotonated ring carbons.     

Arsenic containing heterocycles. II. Confirmation of the structure of benzo[a]-9-chlorophenarsazine 12-chloride by 13C-NMR spectroscopy and spin-lattice relaxation time studies: Possible evidence for the contribution of an 75as-13C mechanism to the relaxation of the arsenic bearing quarternary carbons in the phenarsazine ring system

The product of the reaction of (3-chlorophenyl)-2-naphthylamine with arsenic trichloride has been confirmed to be benzo(a)-9-chlorophenarsazine 12-chloride by ¹³C-nmr spectroscopy and spin-lattice (T₁) relaxation time measurements. A considerable shortening of the spin-lattice relaxation times of the arsenic bearing quaternary carbons, relative to the calculated relaxation times, was observed. This discrepancy has been interpreted in terms of an ⁷⁵As-¹³C dipolar contribution to quaternary carbon relaxation.     

Center of mass displacement and relaxation times of linear alkynes

The carbon-13 chemical shifts and relaxation times of various linear alkynes have been measured. Complexation of these compounds with dicobalt octacarbonyl induces changes in δ's and T₁'s. Unambiguous assignments were obtained from deuterium labelled octynes. The T₁ variations result from the displacement of the center of mass of the aliphatic chain. They are systematic and can thus be used for assignment purposes.     

The reactions of tellurium tetrachloride with aliphatic monoketones

The reactions of 13 aliphatic ketones with tellurium tetrachloride has been studied with proton, carbon-13, and tellurium-125 NMR. Tellurium tetrachloride adds electrophilically to the α-carbon of the enol to form ketonyl tellurium trichlorides. Unsymmetric ketones gave mixtures of isomeric ketonyl tellurium trichlorides. Steric hindrance determines which ketonyl tellurium trichlorides form. Except for the ketonyl tellurium trichloride from 2-butanone, tellurium reacts preferentially with the least substituted α-carbon. Six methyl alkyl ketones also yielded appreciable amounts of diketonyl tellurium dichlorides. In all diketonyl tellurium dichlorides, tellurium is bonded to less hindered methylene carbons.     

1H and 13C NMR spectra of 1-palmitoyl-2-oleyl-sn-glycero-3-phosphorylcholine in CDCl3 solution and in sonicated dispersions in 2H2O

A mixed-acid monounsaturated lecithin, 1-palmitoyl-2-oleyl-sn-glycero-3-phosphorylcholine (POL), has been synthesized by phospholipase A₂ digestion of 1,2 dipalmitoyl-sn-glycero-3-phosphorylcholine followed by reacylation of the lysolecithin with oleic anhydride. ¹H (90 MHz) and ¹³C (25.2 MHz) NMR spectra of POL in CDCl₃ solution and in sonicated dispersions in ²H₂O have been obtained, and spin-lattice relaxation times measured. The relaxation times were characteristic of the type of structure formed and reflect molecular motion within the lecithin molecule in each structure. In both systems the spin-lattice relaxation times increase along the alkyl chains towards the terminal methyl group, showing a corresponding increase in the chain molecular motion, although there are significant differences in the gradation of the changes.     

Carbon-13 NMR spectra of solid bicyclo[3. 3. 1]nonan-9-one. Conformational studies in the solid state

Carbon-13 NMR spectra of solid polycrystalline bicyclo[3.3.1]nonan-9-one and adamantanone have been measured at 315K. The relatively narrow ¹³C linewidths observed for these solids, together with measured spin-lattice relaxation times, indicate that both these solids are orientationally disordered. Observed ¹³C chemical shifts of solid bicyclo[3.3.1]nonan-9-one indicate a twin-chair conformation for the two cyclohexanone rings.     

Geometrical information from 13C spin lattice relaxation times of salicylaldehyde

¹³C NMR spin-lattice relaxation times and nuclear overhauser-enhancement factors of salicylaldehyde and salicylaldehyde-d₁, under conditions of proton noise decoupling were measured to explore the possibilities of using relaxation time measurements to obtain geometrical information. The distances from the hydroxyproton to the two quarternary carbons were obtained in good agreement with microwave data.     

CP/MAS Carbon-13 NMR Study of Spin Relaxation Phenomena of Cellulose Containing Crystalline and Noncrystalline Components

Abstract

Cross-polarization, ¹³C rotating frame spin-lattice relaxation and C laboratory frame spin-lattice relaxation processes have been studied for different cellulose samples by CP/MAS ¹³C NMR spectroscopy. It was found that the CP process can be described by a simple thermodynamic model and relative intensities of the respective resonance lines are consistent with the atomic ratios for the spectra obtained at a contact time of about 1 ms. The observed rotating frame spin-lattice relaxation times T^C ₁₀ were dominantly dependent on the time constant T^D _CH by which ¹³C nuclei were coupled to the ¹H dipolar spin system. It was, therefore, impossible to obtain information about molecular     

NMR Relaxation Studies in Aqueous Solutions of Amino Acids

Abstract

The proton magnetic resonance (PMR) spin-lattice and spin-spin relaxation times (T1 and T2) were measured in aqueous solutions of glycine and L-proline as a function of solute concentrations and at a temperature of 32°C. The relaxation times were measured using Bruker PC 120 NMR process analyser. The relaxation times were found to decrease with increase of solute concentrations. The results are interpreted on the basis of flickering cluster model and hydrogen bond formation between solute and solvent molecules.