Peter M. Tolstoy

H/D isotope effects on the low-temperature NMR parameters and hydrogen bond geometries of (FH)2F− and (FH)3F− dissolved in CDF3/CDF2Cl

Using liquid state 1H, 2H and 19F NMR spectroscopy in the temperature range 110–130 K we have studied the hydrogen-bonded anions (FH)2F− and (FH)3F− and their partially and fully deuterated analogs dissolved in the low-freezing freon mixture CDF3/CDF2Cl, in the presence of (C4H9)4N+ as the counter cation. The spin multiplets of the three isotopologs HH, HD, DD of (FH)2F−, and of the four isotopologs HHH, HHD, HDD, DDD of (FH)3F− have been resolved and assigned. Thus, we were able to determine the zero-, one- and two-bond H/D isotope effects on the hydrogen and fluorine NMR chemical shifts as well as isotope effects on the scalar spin–spin hydrogen–fluorine and fluorine–fluorine coupling constants. Using the valence bond order model these NMR data are related to H/D isotope effects on the hydrogen bond geometries. A semi-quantitative interpretation of the observed long range isotope effects is proposed in terms of an anti-cooperative coupling between the hydrogen bonds within each anion. The experimental data can be rationalized in terms of an empirical NMR isotope sum rule, which is analogous to a similar rule for the vibrational frequencies.

The hydrogen-bonded 2-pyridone dimer model system. 1. Combined NMR and FT-IR spectroscopy study.

2-Pyridone (PD), converting to 2-hydroxypyridine (HP) through a lactam-lactim isomerization mechanism, can form three different cyclic dimers by hydrogen bond formation: (PD)(2), (PD-HP), and (HP)(2). We investigate the complexation chemistry of pyridone in dichloromethane-d(2) using a combined NMR and Fourier transform infrared (FT-IR) approach. Temperature-dependent (1)H NMR spectra indicate that at low temperatures (<200 K) pyridone in solution predominantly exists as a cyclic (PD)(2) dimer, in exchange with PD monomers. At higher temperatures a proton exchange mechanism sets in, leading to a collapse of the doublet of (15)N labeled 2-pyridone. Linear FT-IR spectra indicate the existence of several pyridone species, where, however, a straightforward interpretation is hampered by extensive spectral overlap of many vibrational transitions in both the fingerprint and the NH/OH stretching regions. Two-dimensional IR correlation spectroscopy applied on concentration-dependent and temperature-dependent data sets reveals the existence of the (PD)(2) cyclic dimer, of PD-CD(2)Cl(2) solute-solvent complexes, and of PD-PD chainlike dimers. Regarding the difference in effective time scales of the NMR and FT-IR experiments, milliseconds vs (sub)picoseconds, the cyclic dimers (PD-HP) and (HP)(2), and the chainlike conformations HP-PD, may function as intermediates in reaction pathways through which the protons exchange between PD units in cyclic (PD)(2).

Reaction pathways of proton transfer in hydrogen-bonded phenol-carboxylate complexes explored by combined UV-vis and NMR spectroscopy.

Combined low-temperature NMR/UV-vis spectroscopy (UVNMR), where optical and NMR spectra are measured in the NMR spectrometer under the same conditions, has been set up and applied to the study of H-bonded anions A··H··X(-) (AH = 1-(13)C-2-chloro-4-nitrophenol, X(-) = 15 carboxylic acid anions, 5 phenolates, Cl(-), Br(-), I(-), and BF(4)(-)). In this series, H is shifted from A to X, modeling the proton-transfer pathway. The (1)H and (13)C chemical shifts and the H/D isotope effects on the latter provide information about averaged H-bond geometries. At the same time, red shifts of the π-π* UV-vis absorption bands are observed which correlate with the averaged H-bond geometries. However, on the UV-vis time scale, different tautomeric states and solvent configurations are in slow exchange. The combined data sets indicate that the proton transfer starts with a H-bond compression and a displacement of the proton toward the H-bond center, involving single-well configurations A-H···X(-). In the strong H-bond regime, coexisting tautomers A··H···X(-) and A(-)···H··X are observed by UV. Their geometries and statistical weights change continuously when the basicity of X(-) is increased. Finally, again a series of single-well structures of the type A(-)···H-X is observed. Interestingly, the UV-vis absorption bands are broadened inhomogeneously because of a distribution of H-bond geometries arising from different solvent configurations.

Symmetrization of Cationic Hydrogen Bridges of Protonated Sponges Induced by Solvent and Counteranion Interactions as Revealed by NMR Spectroscopy

The properties of the intramolecular hydrogen bonds of doubly (15)N-labeled protonated sponges of the 1,8-bis(dimethylamino)naphthalene (DMANH(+)) type have been studied as a function of the solvent, counteranion, and temperature using low-temperature NMR spectroscopy. Information about the hydrogen-bond symmetries was obtained by the analysis of the chemical shifts delta(H) and delta(N) and the scalar coupling constants J(N,N), J(N,H), J(H,N) of the (15)NH(15)N hydrogen bonds. Whereas the individual couplings J(N,H) and J(H,N) were averaged by a fast intramolecular proton tautomerism between two forms, it is shown that the sum |J(N,H)+J(H,N)| generally represents a measure of the hydrogen-bond strength in a similar way to delta(H) and J(N,N). The NMR spectroscopic parameters of DMANH(+) and of 4-nitro-DMANH(+) are independent of the anion in the case of CD(3)CN, which indicates ion-pair dissociation in this solvent. By contrast, studies using CD(2)Cl(2), [D(8)]toluene as well as the freon mixture CDF(3)/CDF(2)Cl, which is liquid down to 100 K, revealed an influence of temperature and of the counteranions. Whereas a small counteranion such as trifluoroacetate perturbed the hydrogen bond, the large noncoordinating anion tetrakis[3,5-bis(trifluoromethyl)phenyl]borate B[{C(6)H(3)(CF(3))(2)}(4)](-) (BARF(-)), which exhibits a delocalized charge, made the hydrogen bond more symmetric. Lowering the temperature led to a similar symmetrization, an effect that is discussed in terms of solvent ordering at low temperature and differential solvent order/disorder at high temperatures. By contrast, toluene molecules that are ordered around the cation led to typical high-field shifts of the hydrogen-bonded proton as well as of those bound to carbon, an effect that is absent in the case of neutral NHN chelates.

Encapsulated Carboxylic Acid Dimers with Compressed Hydrogen Bonds

Interacting guests cannot exchangepartners rapidly inside capsules (as they do in bulk solution)and they are separated from solvent molecules by mechanicalbarriers. Instead, the capsule is the solvent, fixed in placearound the solute. Here we report a study on hydrogen-bonded carboxylic acid dimers as guests within an expandedcapsule assembly. It reveals evidence of compression of theguests in the isolated environment of the host.When cavitand 1 and glycoluril 2 (Figure 1) are dissolvedin deuterated mesitylene and suitable guests are present, theracemic capsule 1·2

Geometries and tautomerism of OHN hydrogen bonds in aprotic solution probed by H/D isotope effects on (13)C NMR chemical shifts.

The (1)H and (13)C NMR spectra of 17 OHN hydrogen-bonded complexes formed by CH(3)(13)COOH(D) with 14 substituted pyridines, 2 amines, and N-methylimidazole have been measured in the temperature region between 110 and 150 K using CDF(3)/CDF(2)Cl mixture as solvent. The slow proton and hydrogen bond exchange regime was reached, and the H/D isotope effects on the (13)C chemical shifts of the carboxyl group were measured. In combination with the analysis of the corresponding (1)H chemical shifts, it was possible to distinguish between OHN hydrogen bonds exhibiting a single proton position and those exhibiting a fast proton tautomerism between molecular and zwitterionic forms. Using H-bond correlations, we relate the H/D isotope effects on the (13)C chemical shifts of the carboxyl group with the OHN hydrogen bond geometries.

Solvent and H/D Isotope Effects on the Proton Transfer Pathways in Heteroconjugated Hydrogen-Bonded Phenol-Carboxylic Acid Anions Observed by Combined UV–vis and NMR Spectroscopy

Heteroconjugated hydrogen-bonded anions A···H···X(-) of phenols (AH) and carboxylic/inorganic acids (HX) dissolved in CD2Cl2 and CDF3/CDF2Cl have been studied by combined low-temperature UV-vis and (1)H/(13)C NMR spectroscopy (UVNMR). The systems constitute small molecular models of hydrogen-bonded cofactors in proteins such as the photoactive yellow protein (PYP). Thus, the phenols studied include the PYP cofactor 4-hydroxycinnamic acid methyl thioester, and the more acidic 4-nitrophenol and 2-chloro-4-nitrophenol which mimic electronically excited cofactor states. It is shown that the (13)C chemical shifts of the phenolic residues of A···H···X(-), referenced to the corresponding values of A···H···A(-), constitute excellent probes for the average proton positions. These shifts correlate with those of the H-bonded protons, as well as with the H/D isotope effects on the (13)C chemical shifts. A combined analysis of UV-vis and NMR data was employed to elucidate the proton transfer pathways in a qualitative way. Dual absorption bands of the phenolic moiety indicate a double-well situation for the shortest OHO hydrogen bonds studied. Surprisingly, when the solvent polarity is low the carboxylates are protonated whereas the proton shifts toward the phenolic oxygens when the polarity is increased. This finding indicates that because of stronger ion-dipole interactions small anions are stabilized at high solvent polarity and large anions exhibiting delocalized charges at low solvent polarities. It also explains the large acidity difference of phenols and carboxylic acids in water, and the observation that this difference is strongly reduced in the interior of proteins when both partners form mutual hydrogen bonds.

NMR Studies of Solid Pentachlorophenol-4-Methylpyridine Complexes Exhibiting Strong OHN Hydrogen Bonds: Geometric H/D Isotope Effects and Hydrogen Bond Coupling Cause Isotopic Polymorphism

We have studied the hydrogen bond interactions of (15)N labeled 4-methylpyridine (4-MP) with pentachlorophenol (PCP) in the solid state and in polar solution using various NMR techniques. Previous spectroscopic, X-ray, and neutron crystallographic studies showed that the triclinic 1:1 complex (4-MPPCP) exhibits the strongest known intermolecular OHN hydrogen bond in the solid state. By contrast, deuteration of the hydrogen bond gives rise to the formation of a monoclinic structure exhibiting a weaker hydrogen bond. By performing NMR experiments at different deuterium fractions and taking advantage of dipolar (1)H-(15)N recoupling under combined fast MAS and (1)H decoupling, we provide an explanation of the origin of the isotopic polymorphism of 4-MPPCP and improve previous chemical shift correlations for OHN hydrogen bonds. Because of anharmonic ground state vibrations, an ODN hydrogen bond in the triclinic form exhibits a shorter oxygen-hydron and a longer oxygen-nitrogen distance as compared to surrounding OHN hydrogen bonds, which also implies a reduction of the local dipole moment. The dipole-dipole interaction between adjacent coupled OHN hydrogen bonds which determines the structure of triclinic 4-MPPCP is then reduced by deuteration, and other interactions become dominant, leading to the monoclinic form. Finally, the observation of stronger OHN hydrogen bonds by (1)H NMR in polar solution as compared to the solid state is discussed.

Combined NMR and UV/vis spectroscopy in the solution state: study of the geometries of strong OHO hydrogen bonds of phenols with carboxylic acids.

It has become a routine approach in the structure determinations of organic compounds to employ a set of different methods, such as NMR, IR, Raman, UV/Vis spectroscopy and mass spectrometry, exploiting their complementary benefits. These experiments are usually performed using different samples prepared according to the specific requirements of the particular method. However, different samples of a given system may exhibit a different composition which can lead to a different degree of molecular aggregation and hence molecular conformations. The molecular conformations are temperature and solvent dependent and difficult to analyze. Thus, to ensure the compatibility of spectra obtained by different techniques, measurements performed on the same sample and under the same conditions may be crucial. For this reason, combined methods such as Raman spectroscopy/UV/ Vis spectroscopy/fluorescence spectroscopy, X-ray photoemission spectroscopy/ultraviolet photoemission spectroscopy/flame emission spectroscopy (XPS/UPS/FES), and EPR spectroscopy/UV/Vis spectroscopy/gas chromatography (GC) methods have been proposed. Recently, Hunger and co-workers have described a way to perform combined UV/ Vis absorption and magic-angle spinning (MAS) NMR measurements. This has incited us to combined low-temperature UV/Vis and solution-state NMR spectroscopy (UVNMR) which provides new insights into the acid–base chemistry of strongly hydrogen-bonded complexes dissolved in aprotic solvents. These systems are very sensitive to sample concentration, solvent, 9] and temperature. 9] The use of low-temperature NMR spectroscopy has the advantage that the regime of slow proton exchange between hydrogenbonded complexes can be reached, which allows their NMR parameters and hence information about their structure to be obtained. Moreover, it allows the influence of the solvent polarity which is strongly temperature dependent to be studied. The benefits of UVNMR will be demonstrated using the example of a phenol carboxylate complex dissolved in CD2Cl2. The reason to choose this system is two-fold. Firstly, previous UV/Vis studies indicated that the position of the absorption bands of phenol groups is sensitive to their protonation state, both in protic and aprotic 15] media; however, no information about hydrogen-bond geometries could be derived from UV/Vis measurements alone. Secondly, the UV/Vis spectra of solutions of a phenol with bases generally exhibit broad overlapping absorption bands indicating the presence of several species in different hydrogen bond and protonation states. Herein, we demonstrate that UVNMR allows the electronic excitation frequencies to be correlated with NMR chemical shifts which in turn provide information about hydrogen-bond geometries. To build a combined UVNMR probe an existing Bruker 5 mm low-temperature H–C probe was equipped with a guiding channel for the insertion of a fiber optic reflection probe. The optical probe with six illumination fibers and one read fiber was a custom variation of the regular probe with 200 mm fibers and 2.5 mm tip by Avantes (Eerbeek, Netherlands). In Figure 1, a schematic representation of the measurement region of the modified NMR probe is given. The tip of the optical probe is located centrally underneath the bottom of the NMR sample tube. The illumination fibers are connected to a halogen/deuterium light source (Avantes) and the light reflected to the read fiber is analyzed by a AvaSpec 2048 spectrometer (operating range 240–800 nm). Reflection of sufficient amounts of light is achieved by placing a polytetrafluoroethylene (PTFE) insert inside the sample tube, leaving only a thin layer of solution between the inner glass surface and the bottom of the insert (0.02–0.5 mm, depending on the shape of the insert; the “effective” optical path length can be estimated using solutions of a substance with known extinction coefficient). In this work, the PTFE

Interpretation of Hydrogen/Deuterium Isotope Effects on NMR Chemical Shifts of (FHF) − Ion Based on Calculations of Nuclear Magnetic Shielding Tensor Surface

Abstract Using ab initio calculations of 1H, 19F magnetic shielding tensors of hydrogen difluoride ion as the functions of three coordinates of symmetry, an attempt is made to estimate the contributions of different vibrational isotope effects to H/D NMR isotope shifts referred in the literature. It is shown that the contributions of the amplitudes of proton stretching and bending vibrations dominate whereas the contribution of the totally symmetric vibration can be neglected. Different signs of the H/D isotope effects on hydron and fluorine chemical shifts are caused by very strong angle dependence of the fluorine magnetic shielding. The agreement of the calculated and measured values is nearly quantitative. An unusually strong paramagnetic deshielding of hydrogen for the equilibrium geometry of the [FHF]− ion is noted.