The
hyperpolarization (HP) method signal amplification by reversible exchange
(SABRE) uses para-hydrogen to sensitize substrate
detection by NMR. The catalyst systems [Ir(H)2(IMes)(MeCN)2(R)]BF4 and [Ir(H)2(IMes)(py)2(R)]BF4 [py = pyridine; R = PCy3 or PPh3; IMes = 1,3-bis(2,4,6-trimethylphenyl)imidazol-2-ylidene],
which contain both an electron-donating N-heterocyclic carbene and
a phosphine, are used here to catalyze SABRE. They react with acetonitrile
and pyridine to produce [Ir(H)2(NCMe)(py)(IMes)(PPh3)]BF4 and [Ir(H)2(NCMe)(py)(IMes)(PCy3)]BF4, complexes that undergo ligand exchange on
a time scale commensurate with observation of the SABRE effect, which
is illustrated here by the observation of both pyridine and acetonitrile
HP. In this study, the required symmetry breaking that underpins SABRE
is provided for by the use of chemical inequivalence rather than the
previously reported magnetic inequivalence. As a consequence, we show
that the ligand sphere of the polarization transfer catalyst itself
becomes hyperpolarized and hence that the high-sensitivity detection
of a number of reaction intermediates is possible. These species include
[Ir(H)2(NCMe)(py)(IMes)(PPh3)]BF4, [Ir(H)2(MeOH)(py)(IMes)(PPh3)]BF4, and [Ir(H)2(NCMe)(py)2(PPh3)]BF4. Studies are also described that employ the deuterium-labeled
substrates CD3CN and C5D5N, and the
labeled ligands P(C6D5)3 and IMes-d22, to demonstrate that dramatically improved
levels of HP can be achieved as a consequence of reducing proton dilution
and hence polarization wastage. By a combination of these studies
with experiments in which the magnetic field experienced by the sample
at the point of polarization transfer is varied, confirmation of the
resonance assignments is achieved. Furthermore, when [Ir(H)2(pyridine-h5)(pyridine-d5)(IMes)(PPh3)]BF4 is examined,
its hydride ligand signals are shown to become visible through para-hydrogen-induced polarization rather than SABRE.
The
development of inexpensive and sustainable aluminum(salen)
complexes as catalysts for the kinetic resolution of terminal epoxides
is described. The kinetic resolution is carried out under mild conditions
(0–25 °C and 1 bar of CO2 pressure) in the
presence of tetrabutylammonium bromide as co-catalyst in the absence
of solvent. The relative rate of reaction of the two epoxide enantiomers
(k
rel) is substrate dependent, and the
highest k
rel obtained was 15.4, using N-(2,3-epoxypropyl)diphenylamine as substrate.
Manganese‐catalyzed C−H bond activation chemistry is emerging as a powerful and complementary method for molecular functionalization. A highly reactive seven‐membered MnI intermediate is detected and characterized that is effective for H‐transfer or reductive elimination to deliver alkenylated or pyridinium products, respectively. The two pathways are determined at MnI by judicious choice of an electron‐deficient 2‐pyrone substrate containing a 2‐pyridyl directing group, which undergoes regioselective C−H bond activation, serving as a valuable system for probing the mechanistic features of Mn C−H bond activation chemistry.
Co-crystallisation of, in particular, 4-iodotetrafluorophenol with a series of secondary and tertiary cyclic amines results in deprotonation of the phenol and formation of the corresponding ammonium phenate. Careful examination of the X-ray single-crystal structures shows that the phenate anion develops a C=O double bond and that the CÀC bond lengths in the ring suggest a Meissenheimer-like delocalisation. This delocalisation is supported by the geometry of the phenate anion optimised at the MP2(Full) level of theory within the aug-cc-pVDZ basis (aug-cc-pVDZ-PP on I) and by natural bond orbital (NBO) analyses. With sp 2 hybridisation at the phenate oxygen atom, there is strong preference for the formation of two non-covalent interactions with the oxygen sp 2 lone pairs and, in the case of secondary amines, this occurs through hydrogen bonding to the ammonium hydrogen atoms. However, where tertiary amines are concerned, there are insufficient hydrogen atoms available and so an electrophilic iodine atom from a neighbouring 4-iodotetrafluorophenate group forms an I···O halogen bond to give the second interaction. However, in some co-crystals with secondary amines, it is also found that in addition to the two hydrogen bonds forming with the phenate oxygen sp 2 lone pairs, there is an additional intermolecular I···O halogen bond in which the electrophilic iodine atom interacts with the C=O p-system. All attempts to reproduce this behaviour with 4-bromotetrafluorophenol were unsuccessful. These structural motifs are significant as they reproduce extremely well, in low-molar-mass synthetic systems, motifs found by Ho and co-workers when examining halogenbonding interactions in biological systems. The analogy is cemented through the structures of co-crystals of 1,4-diiodotetrafluorobenzene with acetamide and with N-methylbenzamide, which, as designed models, demonstrate the orthogonality of hydrogen and halogen bonding proposed in Ho's biological study.
A combined computational and experimental study is presented that investigates the mechanism of the anti-Markovnikov hydration of phenylacetylene by [Ru(η(5)-C5H5)(6-DPPAP)(3-DPICon)](+) (where 6-DPPAP = 6-(diphenylphosphino)-N-pivaloyl-2-aminopyridine) and 3-DPICon = 3-diphenylphosphinoisoquinolone). The proposed mechanism, modelled using density functional calculations, involves an initial alkyne-vinylidene tautomerism, which occurs via a ligand-assisted proton shuttle (LAPS) mechanism. Intramolecular ligand assistance from the 6-DPPAP and 3-DPICon ligands, particularly the basic nitrogen of 6-DPPAP, is also involved in subsequent stages of the mechanism and three LAPS processes in total are observed. The self-assembled ligand backbone helps to create a water-binding pocket close to the metal centre, which facilitates nucleophilic attack of water at the vinylidene α-carbon and mediates protonation and deprotonation of subsequent acyl and vinyl intermediates. Experimental evidence is also presented for a novel non-productive catalyst deactivation pathway, which appears to arise from an initial lactam-lactim tautomerism of the 3-DPICon ligand followed by coupling with a vinylidene.
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