Formaldehyde is an important precursor
to numerous industrial processes
and is produced in multimillion ton scale every year by catalytic
oxidation of methanol in an energetically unfavorable and atom-inefficient
industrial process. In this work, we present a highly selective one-step
synthesis of a formaldehyde derivative starting from carbon dioxide
and hydrogen gas utilizing a homogeneous ruthenium catalyst. Here,
formaldehyde is obtained as dimethoxymethane, its dimethyl acetal,
by selective reduction of carbon dioxide at moderate temperatures
(90 °C) and partial pressures (90 bar H2/20 bar CO2) in the presence of methanol. Besides the desired product,
only methyl formate is formed, which can be transformed to dimethoxymethane
in a consecutive catalytic step. By comprehensive screening of the
catalytic system, maximum turnover numbers of 786 for dimethoxymethane
and 1290 for methyl formate were achieved with remarkable selectivities
of over 90% for dimethoxymethane.
Chemical reactions that lead to as pontaneous symmetry breaking or amplification of the enantiomeric excess are of fundamental interesti ne xplaining the formation of ah omochiral world.Ano utstanding example is Soai's asymmetric autocatalysis, in which small enantiomerice xcesses of the added product alcohol are amplified in the reaction of diisopropylzinc and pyrimidine-5-carbaldehydes. The exact mechanism is still in dispute due to complex reaction equilibria and elusive intermediates. In situ high-resolution mass spectrometric measurements, detailed kinetic analyses and doping with in situ reacting reaction mixtures show the transient formationo fh emiacetal complexes, whichc an establish an autocatalytic cycle.W ep ropose a mechanism that explainst he autocatalytic amplification involving these hemiacetal complexes.C omprehensivek inetic experiments and modelling of the hemiacetal formation and the Soai reactiona llow the precise predictiono ft he reaction progress, the enantiomeric excessa sw ell as the enantiomeric excess dependentt ime shift in the induction period. Experimental structurald ata give insights into the privileged properties of the pyrimidyl units and the formationof diastereomeric structures leading to an efficient amplification of even minimalenantiomeric excesses, respectively.
Chiral compounds are ubiquitous in nature and play a pivotal role in biochemical processes, in chiroptical materials and applications, and as chiral drugs. The analysis and determination of the enantiomeric ratio (er) of chiral compounds is of enormous scientific, industrial, and economic importance. Chiral separation techniques and methods have become indispensable tools to separate chiral compounds into their enantiomers on an analytical as well on a preparative level to obtain enantiopure compounds. Chiral gas chromatography and high‐performance liquid chromatography have paved the way and fostered several research areas, that is, asymmetric synthesis and catalysis in organic, medicinal, pharmaceutical, and supramolecular chemistry. The development of highly enantioselective chiral stationary phases was essential. In particular, the elucidation and understanding of the underlying enantioselective supramolecular separation mechanisms led to the design of new chiral stationary phases. This review article focuses on the development of chiral stationary phases for gas chromatography. The fundamental mechanisms of the recognition and separation of enantiomers and the selectors and chiral stationary phases used in chiral gas chromatography are presented. An overview over syntheses and applications of these chiral stationary phases is presented as a practical guidance for enantioselective separation of chiral compound classes and substances by gas chromatography.
The formation of peptide bonds is one of the most important biochemical reaction steps. Without the development of structurally and catalytically active polymers, there would be no life on our planet. However, the formation of large, complex oligomer systems is prevented by the high thermodynamic barrier of peptide condensation in aqueous solution. Liquid sulphur dioxide proves to be a superior alternative for copper-catalyzed peptide condensations. Compared to water, amino acids are activated in sulphur dioxide, leading to the incorporation of all 20 proteinogenic amino acids into proteins. Strikingly, even extremely low initial reactant concentrations of only 50 mM are sufficient for extensive peptide formation, yielding up to 2.9% of dialanine in 7 days. The reactions carried out at room temperature and the successful use of the Hadean mineral covellite (CuS) as a catalyst, suggest a volcanic environment for the formation of the peptide world on early Earth.
Due to the increasing
demand for formaldehyde as a building block
in the chemical industry as well as its emerging potential as feedstock
for biofuels in the form of dimethoxymethane and the oxymethylene
ethers produced therefrom, the catalytic transformation of carbon
dioxide to the formaldehyde oxidation state has become a focus of
interest. In this work, we present novel ruthenium complexes with
hetero-triphos ligands, which show high activity in the selective
transformation of carbon dioxide to dimethoxymethane. We substituted
the apical carbon atom in the backbone of the triphos ligand platform
with silicon or phosphorus and optimized the reaction conditions to
achieve turnover numbers as high as 685 for dimethoxymethane. The
catalytic systems could also be tuned to preferably yield methyl formate
with turnover numbers of up to 1370, which in turn can be converted
into dimethoxymethane under moderate conditions.
An efficient algorithmic workflow was developed to optimize seven process parameters of a homogeneous catalytic system with minimal experimental effort.
A series of different unsymmetrically substituted naphthyl-based diynes were synthesized. These substrates formed the foundation for the assembly of novel biaryls containing pyridine moieties with differently substituted five-membered rings in the backbone of the newly formed heterobiaryl system. The key step for their efficient construction was the photo- and cobalt-catalyzed [2 + 2 + 2] cycloaddition reaction between the corresponding naphthyldiyne and aceto- or benzonitrile. The heterobiaryl products have been isolated and investigated with respect to the configurational stability of their biaryl axis using dynamic chiral HPLC; subtle effects of the substitution pattern on the stability of the axis were observed. For several compounds the activation barriers (ΔG(‡)) of racemization were determined. Suitable substitution of the five-membered ring backbone exemplarily allowed the Co-catalyzed enantioselective cyclization to yield the enantiomerically enriched heterobiaryl.
High-performance liquid chromatography (HPLC) is an indispensable technique to separate, quantify, and identify a broad range of compounds. Recent advances in HPLC technology led to the development of ultrahigh-performance instruments that allow rapid sample analysis with high efficiency. Nevertheless, there is still the opportunity to increase the sample throughput and to improve the signal-to-noise ratio by the application of multiplexing, where the injected samples are encoded with defined sequences. The obtained signal is then deconvoluted to give conventional chromatograms. In this work we present a method and technique which can be easily implemented in commercially available HPLC instruments to perform multiplexing analysis. Using our approach, multiplexing can be performed on standard laboratory equipment by software control and offers an inherent advantage in sensitivity and minimization of analysis time, demonstrated for the analysis of highly diluted polynuclear aromatic hydrocarbon (PAH) samples in water.
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