Determination of exchangeable protons in natural organic matter using a home-made hydrogen/carbon analyser

A home made hydrogen/carbon analyser was used to determine the portion of exchangeable protons in aquatic humic substances. For this purpose, equal sample amounts were dissolved in H2O and D2O, respectively, dried and combusted in a stream of oxygen. The amount of water resulting from combustion was measured by an infrared detector which recorded the OH bending vibration of H2O. The bands stemming from HOD or D2O were not registered by the detection unit. Thus, combustion of organic samples containing exchangeable protons dissolved in D2O resulted in a significantly smaller signal compared to the signal observed for the same sample dissolved in H2O. The relative intensity loss of the H2O signal observed after combustion was used to derive the portion of exchangeable protons in a standard reference material, a humic substance isolated by the International Humic Substances Society (Suwannee River fulvic acid). According to this method about 20% of the sample protons could be identified as exchangeable protons. With regard to titration data the portion of protons bound to non acidic hydroxy functions could be estimated. The validity of this procedure was proved by combustion experiments using commercially available deuterated substances as well as organic model compounds dissolved in D2O and H2O, respectively.     

1H NMR parameters of the N-terminal 13-residue C-peptide of ribonuclease in aqueous solution

The ¹H NMR chemical shifts and the spin-spin coupling constants of the non-exchangeable protons of the N-terminal 13-residue C-peptide of ribonuclease A, obtained by cleavage of the enzyme with cyanogen bromide, have been measured in a 5 mM solution in D₂O (pH 3.0, 24°C) at 360 MHz. The titration parameters for end groups (Lys-1 and homo-Ser-13) and side chains (Lys-1, Glu-2, Lys-7, Glu-9 and His-12) have been determined. The chemical shifts, their temperature coefficients and the vicinal coupling constants, ³J(HNCH-α), for the exchangeable NH protons have been measured in a 5 mM solution in D₂O/H₂O (1:9 v/v) at pH 3.0. An assignment of observed signals to individual residue protons based on characteristic shifts, standard double resonance experiments, spectral simulations and titration shifts is proposed. All experimental evidence indicates that under the conditions studied the C-peptide is in a random coil form.     

Neutron diffraction in D2O salt solutions is no cause of sensitivity changes in prompt gamma or instrumental neutron activation analysis

When slab-shaped samples are analyzed with prompt gamma neutron activation analysis (PGNAA), sensitivity changes can be observed depending on the hydrogen content of the sample. In PGNAA experiments performed by MACKEY at NIST where D₂O solutions were compared to H₂O solutions, it was found that most elements tested showed statistically equal sensitivity increases with increasing hydrogen concentration. Outliers were manganese, hydrogen and samarium. For manganese, it is hypothesized in this paper that the sensitivity for ions dissolved in D₂O is influenced by neutron diffraction due to local ordering of hydrogen bonds. This hypothesis is tested with instrumental activation analysis and falsified.     

Hydration of choline salts studied by NMR relaxation

The concentration dependence of T₁ for protons and deuterons in H₂O and D₂O solutions of three choline salts is anomalously high in dilute solutions. We suggest that this is due to formation of clathrate hydrate shells. Acetylcholine chloride does not show anomalous behaviour.     

CPS K 221 Model of proton longitudinal magnetic relaxation in hydrated crosslinked poly(methacrylic acid)

Proton longitudinal magnetic relaxation time (T₁) measurements have been made at 30 MHz over a wide range of temperature for crosslinked poly(methacrylic acid), PMA, hydrated with H₂O as well as with D₂O. From the point of view of nuclear magnetic relaxation, PMA hydrogel is a multiregion system in which three proton regions (a, b, c) can be distinguished. Region a is regarded as to be formed by the nonexchangeable polymer protons, region b by the protons of -COOH · H₂O combinations, and region c by the protons of remaining water molecules. Cross relaxation between polymer and water protons and a log normal distribution of correlation times have been assumed to take place. Temperature dependences of the T₁ time for the particular regions have been determined, from which the distribution width parameter, the second moment and the intramolecular proton-proton distance for sorbed water have been calculated.     

Bestimmung der Art der Wasserbindung im Xonotlit 6 CaO-6 SiO2-H2O

The ¹H-NMR spectra of powdered synthetic xonotlite (5.64 CaO · 6SiO₂ · 1.56 H₂O) at +22 and ?150°C have been recorded. From the line shape the various bonding states of the protons are determined. Per 6 SiO₂ units, 1.46 H₂O are bound in form of OH groups and 0.20 H₂O exist at room temperature as mobile water molecules. By quantitative evaluation it is shown, that the constitution of the examined sample has to be represented by the formula (CaOH)_2.0Ca_3.6(H_0.8Si₆O₁₇). 0.2 H₂O. Line shape analysis provides the possibility to distinguish between CaOH and SiOH protons. The proton-proton distances are calculated, and by comparison with the known X-ray data the positions of the CaOH protons are proposed.     

Uranyl complexation by monodentate nitrogen donor ligands. A relativistic density functional study

To examine the interaction of uranyl with nitrogen containing groups of humic substances, the model complexes [UO₂(H₂O)₄L_N]²⁺, L_N = NH₂CH₃, N(CH₃)₃, and NC₅H₅ in aqueous solution were studied computationally with an all‐electron relativistic density functional method. Results are compared with the corresponding penta‐aqua complex of uranyl. Although pyridine coordinates with about the same strength as L = H₂O, methylamine binds ～10 kJ mol^?1 stronger and trimethylamine ～40 kJ mol^?1 weaker than a fifth aqua ligand. Yet, each of these ligands L_N donates about the same amount of charge to uranyl as L = H₂O. U? N bonds are ～10 pm longer than the U? O bonds of the aqua ligands. From the present model results, one does not expect that, when compared with carboxyl groups, monodentate N‐containing functional groups contribute significantly to uranyl complexation by humic substances. © 2010 Wiley Periodicals, Inc. Int J Quantum Chem, 2011     

Absorption of light and heavy water vapours in polyelectrolyte multilayer films

We studied the swelling and the uptake of water (H₂O or D₂O) vapours in polyelectrolyte (PE) multilayer (PEM) samples deposited on solid support (Si wafers) as a function of the isotope nature of the vapour and the charge of the last polymer layer. The samples were prepared with deuterated poly(sodium 4-styrenesulfonate) (dPSS) and poly(allylamine hydrochloride) (PAH). Two types of samples were studied. The sample with a structure Si/PEI/(dPSS/PAH)₆/dPSS was negatively charged. A positively charged sample was PAH terminated and had the structure Si/PEI/(dPSS/PAH)₆. The film thickness and scattering length density were estimated from neutron reflectometry (NR) experiments and the results were complemented with in-situ QCM measurements.We demonstrate that the swelling of PEM in H₂O and D₂O vapours is similar. However, the amount of adsorbed D₂O is around 10% more than the adsorbed H₂O. Such isotope effect correlates well with the rough estimation that the isotope effect usually scales with the difference in the mass density of the different isotope forms of the substances. For precise analysis of the NR data we assumed existence of empty voids in the structure of the PEM. These voids might be filled with “condensed” water when the samples are exposed to water vapors. We show that the layers we studied consist of up to 25% of such voids.We showed that the amount of sorbed water depends on the nature of the last layer which builds the PEM thus confirming the “odd-even effect” already shown in the literature.     

Isotopic fractionation during pretreatment for accelerator mass spetrometer measurement of (D<Subscript>3</Subscript>C)<Subscript>2</Subscript>O containing <Superscript>14</Superscript>C produced by nuclear reaction

A (D₃C)₂O (d₆-acetone) target was irradiated with semi-monoenergetic neutrons generated from ⁹Be(p,n)⁹B reaction with 20 MeV protons to convert ¹³C and oxygen nuclides in the target into ¹⁴C. With both liquid scintillation counting (LSC) and accelerator mass spectrometry (AMS) we measured the (D₃C)₂O (d₆-acetone) liquid targets, which were combustible and easy to afford CO₂ for the AMS measurements. The ¹⁴C yield measured by the LSC method turned out to be 80 times larger than that by the AMS method. This large discrepancy may be attributed to the loss of ¹⁴C atoms during the sample pretreatment in the AMS method such as combustion and cryogenic trapping of CO₂. It means that ¹⁴C newly produced by nuclear reactions can exist in various chemical forms, i.e., C₃D₆O, CO, CO₂, hydrocarbons, etc., and a simple sample pretreatment right after production can cause serious isotopic fractionation. Therefore, using the AMS method, extreme caution in sample pretreatment should be exercised when the ¹⁴C yield produced immediately by nuclear reaction is measured.     

Deuterated Digoxin

Abstract

A method for preparing [21,21,22-²H₃] digoxin by proton exchange with D₂O under high temperature and basic conditions is described. Loss of signal for the protons at C₂₁ and C₂₂ upon deuteration, with retention of structural integrity for the remainder of the parent compound, is established with high resolution proton NMR spectroscopy. Confirmation of the site of deuterium exchange and relative abundance of the species ²H₀:²H₁:²H₂:²H₃ is demonstrated by capillary gas chromatography - mass spectrometry (GC-MS) of the trimethylsilyl derivative of the steroidal component of digoxin, digoxigenin.     

Radiospectroscopic method for determining contents of deuterium and tritium in aqueous solutions

Radio-wave emission spectra in the microwave region are registered for the first time for ordinary water (H₂O), heavy water (D₂O), and D₂O with a low content of T₂O. The obtained spectra are analyzed according to a special program using a hardware–software complex. Measurement results show that the proposed method allows us not only to determine differences between substances in terms of composition and concentration, but to determine the presence of heavy and superheavy hydrogen isotopes in ordinary water as well.     

D2O–H2O solvent isotope effects on the volumetric properties of aqueous 1,3-dimethyl-2-imidazolidinone between (278.15 and 318.15) K

Densities of dilute solutions of 1,3-dimethyl-2-imiazolidinone in H₂O and D₂O, with the solute mole-fractions ranging up to 0.01, have been measured with an error of 1.5 · 10⁻⁵ g · cm⁻³ at (278.15, 288.15, 298.15, 308.15, 313.15, and 318.15) K and atmospheric pressure using a vibrating-tube densimeter. The partial molar volumes of the dissolved DMI (down to the infinite dilution) and solvent (H₂O or D₂O) as well as the excess molar volumes of the isotopically distinguishable solutions have been calculated. The effects of the solvent isotope substitution, solute concentration and temperature on the volume changes caused by DMI hydration have been considered. The obvious relationship between the D₂O–H₂O solvent isotope effects on the partial molar volume and enthalpy of solution of DMI has been discovered.     

Mass spectrometric comparison of ordinary and fully deuterated α- and β-carotene

The individual, deuterated, isomeric α- and β-carotenes were isolated from the green alga, Scenedesmus obliquus, cultivated in D₂O containing 99·7 to 99·8 atom percent deuterium. Mass spectroscopy showed that both the α- and β-deuterio-carotene preparations contained principally the fully deuterated pigment molecules (C₄₀D₅₆), small quantities of deuterated molecules with one proton (C₄₀D₅₅H) and yet smaller quantities of deuterated molecules with two protons (C₄₀D₅₄H₂). From statistical calculations the deuterio-carotene preparations also contained one to several isotopically-substituted deuterio-carotenes of each mass in the mass range 585 to 599 because of variation of the number of ¹³C and H atoms per molecule. The mass fragmentation of the deuterated pigments was analogous to that of the respective ordinary α- and β-carotene. It indicated that the protons in the C₄₀D₅₅H and C₄₀D₅₄H₂ molecules were distributed approximately randomly in various parts of the structure as in the terminal rings and in the ends and central portions of the polyene chain.     

A Facile Strategy for the Construction of Purely Organic Optical Sensors Capable of Distinguishing D2O from H2O

Owing to the quite similar chemical properties of H₂O and D₂O, rational molecular design of D₂O optical sensors has not been realized so far. Now purely organic chromophores bearing OH groups with appropriate pK_a values are shown to display distinctly different optical responding properties toward D₂O and H₂O owing to the slight difference in acidity between D₂O and H₂O. This discovery is a new and facile strategy for the construction of D₂O optical sensors. Through this strategy, ratiometric colorimetric D₂O sensor of NIM‐2F and colorimetric/fluorescent dual‐channel D₂O sensor of AF were acquired successfully. Both NIM‐2F and AF can not only qualitatively distinguish D₂O from H₂O by the naked eye, but also quantitatively detect the H₂O content in D₂O.     

Tetracyanonickelate compounds as sorptive materials and the substitution of their H2O content by D2O

The compounds NiNi(CN)₄·3,5H₂O and Ni(NH₃)₂Ni(CN)₄·H₂O have been studied to examine the possibility of substituting their H₂O or NH₃ content by D₂O. Contact with D₂O was performed after heating the compounds to several temperatures. Depending on the degree of decomposition of the original compounds different ranges of substitution were possible. In such manner the compounds NiNi(CN)₄·3,5D₂O, NiNi(CN)₄·5D₂O, Ni(NH₃)₂Ni(CN)₄·D₂O, and Ni(D₂O)₂Ni(CN)₄·D₂O were prepared and thermally they were less stable than the original ones. The substitution by D₂O is in agreement with the sorptive properties of the original tetracyanonickelate against different organic compounds using GC, since these could substitute the guest component and sometimes also the ligands during their decomposition.     

Search for hydrophobic association between small aprotic solutes from an application of the nuclear magnetic relaxation method

Proton and deuteron magnetic relaxation rates of the four solutes acetone, acetonitrile, trimethylamine, and tetramethylurea in their aqueous mixtures are reported. For the normal and deuterated organic substances the water was D₂O and H₂O, respectively. The intermolecular relaxation rates were determined. Experimental results for the self-diffusion coefficients of trimethylamine and tetramethylurea in their aqueous mixtures are also reported. From these results and literature data the A parameter, A=(1/T₁)_inter·D₁/c_′1 being a criterion for association, was calculated. We obtained the result that only for the largest solute molecule, i.e. tetramethylurea, A showed the typical concentration dependence indicating solute-solute association. For the other three components self-association is not outside the range of the sensitivity of the present method.     

Simultaneous Sensing of H2O,D2O and HOD through Peroxo Vibrations

Detection of HOD simultaneously in the presence of a mixture of H₂O and D₂O is still an experimental challenge. Till date, there is no literature report of simultaneous detection of H₂O, D₂O and HOD based on vibrational spectra. Herein we report simultaneous quantitative detection of H₂O, D₂O and HOD in the same reaction mixture with the help of bridged polynuclear peroxo complex in absence and presence of Au nanoparticles on the basis of a peroxide vibrational mode in resonance Raman and surface enhanced resonance Raman spectrum. We synthesize bridged polynuclear peroxo complex in different solvent mixture of H₂O and D₂O. Due to the formation of different nature of hydrogen bonding between peroxide and solvent molecules (H₂O, D₂O and HOD), vibrational frequency of peroxo bond is significantly affected. Mixtures of different H₂O and D₂O concentrations produce different HOD concentrations and that lead to different intensities of peaks positioned at 897, 823 and 867 cm⁻¹ indicating H₂O, D₂O and HOD, respectively. The lowest detection limits (LODs) were 0.028 mole fraction of D₂O in H₂O and 0.046 mole faction of H₂O in D₂O. In addition, for the first time the results revealed that the cis-peroxide forms two hydrogen bonds with solvent molecules.     

Structural Peculiarities of Dioxane Media in H/D Isotope Effects of Water Solvation at 288.15K-318.15K

Using the data of precision densimetry measurements for diluted solutions of H₂O and D₂O in 1,4-dioxane (1,4-DX) at 288.15 K-318.15 K we calculated the limiting partial molar volumes of the H/D isotopomers of water in dioxane and the excess molar volumes of the stated systems. The water molecules dispersed in 1,4-DX form complexes H-bonded into associates whose packing coefficient slightly exceeds that of the structural aggregates in liquid H₂O and D₂O. It is concluded that the structure of 1,4-DX is loosened and concomitantly undergoes volume expansion caused by the water microimpurities. The differentiating temperature effect on the volume solvation effects of H₂O and D₂O in 1,4-DX has been found.Original Russian Text Copyright © 2004 by. E. V. Ivanov, E. Yu. Lebedeva, and V. K. Abrosimov__________Translated from Zhurnal Strukturnoi Khimii, Vol. 45, No. 5, pp. 852–861, September–October, 2004.     

Raman spectral study of solid and dissolved poly(vinyl alcohol) and ethylene-vinyl alcohol copolymer

We have measured the Raman spectra of ethylene-vinyl alcohol copolymer (EVOH) and poly(vinyl alcohol) (PVOH). Spectra of 88% hydrolyzed PVOH were examined from the partially crystalline solid, from PVOH dissolved in both H₂O and D₂O, and from films precipitated from these solutions. The spectrum in H₂O differs from that of the starting material by disappearance of sharp bands having Raman shift values of 1146 and 1093 cm^?1, strengthening of a band near 915 cm^?1, decrease in frequency of bands at 480, 1356, and 1441 cm^?1, and increase in frequency of bands at 369, 413, 1023, 1371, and 2910 cm^?1. The spectrum of the film shows partial reversal of these trends. With D₂O as the solvent, the band shifts are slightly different from those listed above and new bands appear. These changes are indicative of loss of crystallinity, change in stereochemistry, and partial deuteration of hydroxyl during dissolution of this PVOH sample at room temperature. © 1994 John Wiley & Sons, Inc.     

Synthesis, Crystal Structure, and IR Spectroscopic Characterization of 1,6-Hexanediammonium Dihydrogendecavanadate

Summary.  Anhydrous 1,6-hexanediammonium dihydrogendecavanadate ((HdaH₂)₂H₂V₁₀O₂₈, 1) was prepared by reaction of V₂O₅ with 1,6-hexanediamine in aqueous solution. The crystal structure of 1 was determined, and the proton positions in the H₂V₁₀O₂₈ ⁴⁻ anion were calculated by the bond length/bond number method. The protons are bound to the centrosymmetrically oriented μ–OV₃ groups of the decavanadate anion. Based on the analysis of IR spectra of 1 prepared from H₂O and D₂O, the absorption band at 871 cm⁻¹ can be attributed to δ(V–O_b–H) vibrations. Received August 3, 2001. Accepted (revised) October 8, 2001