Functional groups, organic alkyne

Further exploration of the higher activity of the Ni complexes compared to Pd analogs led to the discovery of a novel nano-sized catalytic system with superior performance for hydrothiolation and hydroselenation reactions of alkynes [ 152,153]. Furthermore, it was found that with a simple catalyst precursor - Ni(acac)2 - the reaction was carried out with excellent yields and excellent selectivity, even at room temperature. Both terminal and internal alkynes were successfully involved in the addition reaction. This catalytic system was tolerant to various functional groups in alkynes and was easily scaleable for the synthesis of 1-50 g of product (Scheme 3.85) [152, 153]. The proposed mechanism of the catalytic reaction involved (i) catalyst self organization with nano-sized particles formation, (ii) alkyne insertion into the Ni—Z bond and (iii) protonolysis with RZH (Scheme 3.86). 

The sequence of chapters and topics in Organic Chemistry do not differ markedly from that of other organic chemistry textbooks. Indeed, the topics are presented in the traditional order, based on functional groups (alkenes, alkynes, alcohols, ethers, aldehydes and ketones, carboxylic acid derivatives, etc.). Despite this traditional order, a strong emphasis is placed on mechanisms, with a focus on pattern recognition to illustrate the similarities between reactions that would otherwise appear unrelated (for example, ketal formation and enamine formation, which are mechanistically quite similar). No shortcuts were taken in any of the mechanisms, and all steps are clearly illustrated, including all proton transfer steps. 

Like the haloalkanes, each of the major classes of organic compounds is characterized by a particular functional group. For example, the carbon-carbon triple bond is the functional group of alkynes (Chapter 13) the smallest alkyne, acetylene, is the chemical burned in a welder s torch. A carbon-oxygen double bond is characteristic of aldehydes and ketones (Chapter 17) formaldehyde and acetone are major industrial commodities. The amines... 

The hydrozirconation reaction of alkynes tolerates the presence of a large variety of functional groups. As a consequence, this protocol has become very popular in organic synthesis [135-142]. 

Hydroamination of alkynes offers a straightforward preparation of a variety of amines, enamines, and imines.79 Numerous reports have appeared in the literature on this process. However, almost all these reactions have been carried out in organic solvents, which usually require the protection of functional groups or harsh conditions. Recently, Marinelli et al. have reported an Au(III)-catalyzed hydroamination of alkynes in... 

Click chemistry refers to the reaction between an azido functional group and an alkyne to form a [3 + 2] cycloaddition product, a 5-membered triazole ring. This reaction has been used for many years in organic synthesis to form heterocyclic rings. Normally, the click reaction requires high temperatures, and this was the main reason that it was not used as a bioconjugation tool. However, it was discovered that in aqueous solutions and in the presence of Cu(I), the reaction kinetics are dramatically accelerated to provide high yields even at room temperature and ambient pressures (Rostovtsev et al., 2002 Tornoe et al., 2002 Sharpless et al., 2005). 

With the bulky metallo-organic Pd(II) catalyst 98, on the other hand, selective formation of 99 was possible here functional groups are tolerated that would react with an Ag(I) catalyst (for example, terminal alkynes, alkyl chlorides, alkyl bromides and alkyl iodides) [59]. With l,n-diallenyl diketones (100), easily accessible by a bidirectional synthesis, up to 52-membered macrocycles (101) could be prepared in an end-group differentiating intramolecular reaction (Scheme 15.26) [60], For ring sizes lager than 12 only the E-diastereomer is formed overall yields of the macrocydes varied between 17 and 38%. Only with tethers shorter than 11 carbon atoms could the Z-diastereomer of the products be observed, a stereoisomer unknown from the intermolecular dimerization reactions of 96. 

In Organic I you probably started with the hydroccirbons, compounds of carbon and hydrogen, including the alkenes and alkynes that contained double and single bonds, respectively. Then you probably touched on some of the more common functional groups, such as alcohols and maybe even some aromatic compounds. 

As terminal alkynes and ethynyl alcohols are the convenient sources to generate ruthenium vinylidene and allenylidene intermediates, many carbocyclizations have been achieved via nucleophilic addition and other activations at the two intermediates. Most reported carbocyclizations appear to be synthetically useful, not only because of their chemoselectivities but also because of their tolerance toward organic functional groups. Additional examples of catalytic carbocyclization based on ruthenium vinylidenes are still growing, and on the basis of the concepts developed here one can expect to see many new applications in the near future. 

The extent of acetylene insertion can be limited by the control of reaction conditions, such as the ratio of reactant acetylene to the number of Si-Si bonds or reaction time. In addition, if an organic substrate with two alkyne functional groups is used, cross-linked polymers are formed. Other palla-... 

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