Aromatic hydrocarbons are among the most important building blocks in the chemical industry. Benzene, toluene and xylenes are obtained from the high temperature thermolysis of alkanes. Higher alkylaromatics are generally derived from arene-olefin coupling, which gives branched products--that is, secondary alkyl arenes--with olefins higher than ethylene. The dehydrogenation of acyclic alkanes to give alkylaromatics can be achieved using heterogeneous catalysts at high temperatures, but with low yields and low selectivity. We present here the first catalytic conversion of n-alkanes to alkylaromatics using homogeneous or molecular catalysts--specifically 'pincer'-ligated iridium complexes--and olefinic hydrogen acceptors. For example, the reaction of n-octane affords up to 86% yield of aromatic product, primarily o-xylene and secondarily ethylbenzene. In the case of n-decane and n-dodecane, the resulting alkylarenes are exclusively unbranched (that is, n-alkyl-substituted), with selectivity for the corresponding o-(n-alkyl)toluene.
Inexpensive cobalt catalysts derived from N-heterocylic carbenes (NHC) allowed efficient catalytic C-H bond arylations on heteroaryl-substituted arenes with widely available aryl chlorides, which set the stage for the preparation of sterically hindered tri-ortho-substituted biaryls. Likewise, challenging direct alkylations with β-hydrogen-containing primary and even secondary alkyl chlorides proceeded on pyridyl- and pyrimidyl-substituted arenes and heteroarenes. The cobalt-catalyzed C-H bond functionalizations occurred efficiently at ambient reaction temperature with excellent levels of site-selectivities and ample scope. Mechanistic studies highlighted that electron-deficient aryl chlorides reacted preferentially, while the arenes kinetic C-H bond acidity was found to largely govern their reactivity.
The adamantyl-substituted pincer-ligand precursor AdPCP-H [(AdPCP = κ3-C6H3-2,6-(CH2PAd2)2); Ad = 1-adamantyl] has been synthesized by the reaction of 1,3-dibromoxylene with di-1-adamantylphosphine in the presence of triethylamine. Treatment of AdPCP-H with [Ir(COD)Cl]2 (COD = 1,5-cyclooctadiene) affords the pincer-ligated complex (AdPCP)IrHCl, which was crystallographically characterized. Dehydrohalogenation of (AdPCP)IrHCl either with LiBEt3H or with KOtBu, under hydrogen atmosphere, yields the hydrides (AdPCP)IrH2 and (AdPCP)IrH4. (AdPCP)IrH2 catalyzes dehydrogenation of alkanes with a level of activity comparable to that of the previously reported (tBuPCP)IrH2, while it is thermally much more robust than the tBuPCP analogue, as well as iPrPCP or tBuPOCOP pincer complexes.
Both the bisphosphine and bisphosphinite pincer complexes ( tBu4 PCP)IrH 2 and ( tBu4 POCOP)IrH 2 can cocatalyze alkane metathesis in tandem with olefin metathesis catalysts, but the two complexes have different resting states during catalysis, suggesting that different steps are turnoverlimiting in each case. This led to the hypothesis that a complex with intermediate properties would be catalytically more active than either of these two species. Accordingly, "hybrid" phosphine−phosphinite pincer ligands (PCOP) and the corresponding iridium complexes were synthesized (3c−e). In tandem with olefin-metathesis catalyst MoF12, ( tBu4 PCOP)-IrH 2 displays significantly higher activity for the metathesis of n-hexane than does ( tBu4 PCP)IrH 2 or ( tBu4 POCOP)IrH 2 . ( tBu2 PCOP iPr2 )IrH 4 (3d) is even more active (>30-fold more active than ( tBu4 POCOP)IrH 2 ) and affords nearly 4.6 M alkane products after 8 h at 125 °C.
The quinoline-based
pincer nickel(II) complexes κN
,κ
N
,κ
N-{R2N-C6H4-(μ-N)-C9H6N}NiX
((R2NNNQ)NiCl: R
= Me, 2a; R = Et, 2b) were synthesized by
the reaction of the ligand precursors (R2NNNQ)H (R = Me, 1a; R = Et, 1b) with (DME)NiCl2 in the presence of Et3N. Similarly, the pincer
nickel(II) derivatives (R2NNNQ)NiX (R = Me,
X = Br, 3a; R = Et, X = Br, 3b; R = Me,
X = OAc, 4a) were obtained by treatment of the ligands
(R2NNNQ)H with the nickel precursor (THF)2NiBr2 or Ni(OAc)2. All of these complexes
were characterized by 1H and 13C NMR spectroscopy
as well as by elemental analysis. Further, the molecular structures
of 2a and 3a,b were elucidated
by X-ray crystallography. Complex 2a is found to be an
efficient catalyst for the direct C–H bond alkylation of substituted
benzothiazoles and oxazoles with various unactivated alkyl halides
containing β-hydrogens under mild reaction conditions. The catalyst 2a is very robust and was recycled and reused five times for
the alkylation reaction without a decrease in its catalytic activity.
Preliminary studies reveal that the catalyst 2a acts
as an active catalyst and the alkylation reaction appears to operate
via a radical pathway.
The efficient generation of biaryl compounds and heterocycles via the advent of the transition-metal-free coupling reaction constitutes an important development in the last few years. Although early methods for the construction of such molecules involved transition metals, recent advances in the field have witnessed a myriad of elegant reports without the use of metal sources. The serendipitous discovery and observation of synthetic chemists have realized that there lies a great potential in exploiting the inherent reactivity of molecules in absence of transition metal. The key to the success of such coupling reactions is the use of a strong base, oxidant and a catalytic amount of N-donor ligands which contribute significantly. This review aims to highlight the recent progress in the field of transition-metal-free direct C-C and C-heteroatom bond forming reactions via the use of a strong base and (or) an oxidant.
A nickel-catalyzed
direct C-2 alkylation of indoles through monodentate-chelation
assistance has been described. This reaction proceeds via an unusual
strategy by the use of a well-designed and defined (quinolinyl)amido–nickel
catalyst, [{κN,κN,κN-Et2NCH2C(O)(μ-N)C9H6N}Ni(OAc)], providing a solution to the limitations associated with
bidentate-chelate auxiliaries. The method allows coupling of indoles
with various unactivated primary and secondary alkyl halides with
ample substrate scope. This uniquely strategized alkylation proceeded
through crucial C–H activation and via an alkyl radical intermediate.
The reaction by this approach represents a rare example of Ni-catalyzed
monodentate-chelate-assisted C–H functionalization.
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