Alkyl bromides palladium bromide

A tandem palladium-catalysed ort/io-alkylation/intramolecular Heck reaction coupling sequence was used effectively to access in fair yields the tetrahydro 1-benzoxepines 67 from the iodoaryl precursor 66 and the appropriate alkyl bromide. The norbornene plays a relay role in the proposed reaction cycle <06JOC4937>... 

Crucially, this allows organozinc reagents to be prepared from less reactive aryl bromides and secondary or tertiary alkyl bromides. Alternatively, organozinc iodides can be prepared by means of a palladium(0)-catalyzed reaction between alkyl iodides and Et2Zn (Scheme 2.25) [53-56]. 

Die reduktive Debenzylierung mit Ammonium-formiat in Gegenwart von Palladium/Koh-le wird bei einer Methode zur Umwandlung von Alkyl-bromiden in primare Amine genutzt, bei welcher man das Alkyl-bromid zunachst mit Dibenzylamin zum Alkyl-di-benzyl-amin umsetzt und dieses dann reduktiv spaltet1. 

Recently, Fu and coworkers have shown that secondary alkyl halides do not react under palladium catalysis since the oxidative addition is too slow. They have demonstrated that this lack of reactivity is mainly due to steric effects. Under iron catalysis, the coupling reaction is clearly less sensitive to such steric influences since cyclic and acyclic secondary alkyl bromides were used successfully. Such a difference could be explained by the mechanism proposed by Cahiez and coworkers (Figure 2). Contrary to Pd°, which reacts with alkyl halides according to a concerted oxidative addition mechanism, the iron-catalyzed reaction could involve a two-step monoelectronic transfer. 

Alkylation and deprotection of N-protected aminomethylphosphonate esters 6 are shown in Scheme 6. The nitrogen is protected as the imine derived from benzophenone or a benz-aldehyde, and a variety of conditions are used for deprotonation and alkylation (Table 2). The benzaldehyde imine of aminomethylphosphonate can be deprotonated with LDA and alkylated with electrophilic halides (entries 1 and 2). For the best yields, saturated alkyl bromides require an equivalent of HMPA as an additive. 36 Allylic esters can be added to the carbanion with palladium catalysis (entries 3-7). 37,38 For large-scale production, phase-transfer catalysis appears to be effective and inexpensive (entries 8-12). 39,40 ... 

Unsymmetricatl ketones can be obtained by the palladium-catalyzed carbonylation of aryl, alkyl and vinyl bromides and iodides in the presence of tetraalkyl- or tetraaryl-tin compounds (equation 113).489,490 The catalyst precursors used were complexes (102), (107) and [PdCI2(AsPh3)2]. 

Free-radical cyclization reactions nicely complement the Pd(0)-catalyzed intramolecular Heck reaction, which also provides cyclic products from unsaturated halides. Free radicals can be generated easily at saturated carbons from saturated alkyl bromides, and the products are reduced relative to the reactants. In contrast, intramolecular Heck reactions work best for vinyl and aryl bromides (in fact they do not work for alkyl halides), and the products are at the same oxidation level as the reactants. Moreover, free radicals attack the double bond at the internal position, whereas palladium insertion causes cyclization to occur at the external carbon. 

Radical cyclization reactions can be carried out by treating an unsaturated alkyl iodide or bromide with Et2Zn in the presence of palladium(II) or nickel(II) complexes.28 Under these conditions, an intermediate Pd(0) or Ni(0) complex is formed which initiates a radical chain reaction providing a new cyclized zinc cyclopentylmethyl derivative which can be trapped with various electrophiles in the presence of a copper catalyst. A related cyclization can be... 

Altenhoff G, Wiirtz S, Glorius F (2006) The first palladium-catalyzed Sono-gashira coupling of unactivated secondary alkyl bromides. Tetrahedron Lett 47 2925-2928... 

Various metals, when treated with aqueous (1) or other alkyl iodides under flow conditions, showed marked dissolution into water (91,94-96). Dissolution also occurred under static conditions (92,95,97). Initially, these studies used metals more active than hydrogen (Fe, Cr, Ni, Zn, Sn, Pb, Mn) however, Cu was also found to undergo similar dissolution. Preliminary investigations indicated that metallic silver readily formed silver bromide in the presence of alkyl bromides and that palladium dis-... 

Suitable cleaving agents include organic halides such as primary alkyl bromides, iodides or sulfo-nates " ° allylic," - allenic and propargylic bromides vinylic or aryl halides with nickel or palladium promoters " alkyl chloroformates epoxides and even cyanogen or cyanogen bromide. Typical examples of such couplings are depicted in equations (55)-(57). 

In neutral or acidic medium, unactivated primary and secondary alkyl chlorides and bromides are not hydrogenolyzed over palladium, but iodides, as well as tertiary chlorides and bromides, are lost to some extent at least, on hydrogenation at room temperature and atmospheric pressure. 23. 24 an yi fluorides,... 

While optimizing the reaction conditions, Lautens found that cyanation took place with many intermediates in the Catellani reaction sequence, as all non-palladacycle palladium(II) species in the sequence underwent cyanation (Scheme 29). Through optimization experiments, the target product could be obtained in good to excellent yields from either tethered or intermolecular alkyl bromides and iodides (Scheme 30). As alkyl chlorides are more widely commercially available, lower in cost, and more stable than the corresponding alkyl bromides or iodides, Lautens reported a method to incorporate alkyl chlorides as reaction partners. This study eventually led to the use of benzyl chlorides, a-chloroesters, and a-chloroamides as coupling partners, which were far too reactive as the analogous bromides or iodides. 

We could thus expect that this reaction terminated the palladium- and nor-bornene-catalyzed reaction sequence in place of the acrylic ester or terminal olefins in general. Considerable difficulties were met, however, because the alkyne interacted with all the palladium complexes of the sequence, giving rise to a number of by-products. Starting from 1 equivalent of aryl iodide, 2 equivalents of alkyl bromide, 1 equivalent of norbornene, 0.3 equivalents of aryl-acetylene, 8 equivalents of KOAc, and 0.1 equivalent of Pd(OAc)2 and adding gradually 2 equivalents of alkyl bromide and 0.7 equivalents of arylacetylene (to keep the concentration of the latter low) satisfactory results were obtained. Equation 30 reports the reaction withp-fluoroiodobenzene, n-propyl bromide, and phenylacetylene, which gave a 79% yield (71% with iodobenzene) [37]. 

In 2001, Fu reported the first examples of palladium-catalyzed Suzuki reactions of unactivated alkyl bromides (Eq. 2) [ 12]. This study arose from earlier investigations by Fu that had demonstrated the utility of bulky, electron-rich phos-... 

Two reports have described palladium-catalyzed Stille cross-couplings of unactivated alkyl electrophiles. Specifically, these investigations by Fu demonstrate that primary alkyl bromides and iodides can be coupled with vinylstannanes [27,28] and arylstannanes [28] (Eq. 10). 

In the initial study, which focused on palladium-catalyzed cross-couplings of primary alkyl bromides with vinylstannanes, use of P(t-Bu)2Me provided the best yields (solvent=THF) [27]. PCy3 was slightly less effective, whereas a variety of other ligands, including JV-heterocyclic carbenes, were essentially ineffective. The choice of activator (Me4NF) and the presence of molecular sieves were important for the success of these reactions. Some examples of Pd/P(t-Bu)2Me-catalyzed Stille couplings of alkyl bromides with vinylstannanes are provided in entries 1-3 of Table 6. 

Remarkably, cross-couplings of alkyl boranes with alkyl bromides or even chlorides are possible using the catalyst [Pd2(dba)3] and the ligand tricyclohexylphos-phine, PCys (Cy = CeHn). For example, the alkyl chloride 203 was coupled to the alkyl borane 204 (prepared by chemoselective hydroboration with 9-BBN see Section 5.1) to give the product 205 (1.206). The [Pd2(dba)3]/PCy3 catalyst system overcomes the normally slow oxidative addition of the alkyl halide to the palladium and promotes cross-coupling to alkyl boranes in preference to p-hydride elimination. Such B-alkyl Suzuki reactions are likely to be used as key carbon-carbon bond-forming reactions in future synthetic sequences. 

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