Paul L. Alsters

N-Hydroxyphthalimide/Cobalt(II) Catalyzed Low Temperature Benzylic Oxidation Using Molecular Oxygen

Abstract A variety of (substituted) aryl glyoxylates is formed in good to excellent yield under very mild conditions by direct oxidation of the corresponding arylacetic esters or mandelic acid esters with molecular oxygen and N-hydroxyphthalimide/cobalt(II) acetate as catalyst. Heteroaromatic analogs are more difficult to oxidize with this system. The effect of substitution in the aromatic ring of N-hydroxyphthalimide on the oxidation of ethylbenzene has been studied. Electron withdrawing substituents accelerate the oxidation of ethylbenzene and promote the formation of acetophenone. Electron donating substituents lead to decreased rates of oxidation and enhance the selectivity for 1-phenylethanol.

Homogeneous cis-dihydroxylation and epoxidation of olefins with high H2O2 efficiency by mixed manganese/activated carbonyl catalyst system

Abstract The use of [Mn2O3(tmtacn)2](PF6)2 (tmtacn=1,4,7-trimethyl-1,4,7-triazacyclononane) in combination with glyoxylic acid methylester methyl hemiacetal (GMHA) results in a highly active and hydrogen peroxide efficient catalyst for the epoxidation of olefins as well as the first homogeneous catalytic cis-dihydroxylation system with H2O2 and with turnover numbers up to 420.

Manganese catalysed asymmetric cis-dihydroxylation with H2O2

High turnover enantioselective alkene cis-dihydroxylation is achieved with H(2)O(2) catalysed by manganese based complexes containing chiral carboxylato ligands.

Singlet oxygen generation from H2O2/MoO42-: peroxidation of hydrophobic substrates in pure organic solvents

Abstract Seventeen organic solvents are screened as reaction media to conduct the molybdate-catalyzed disproportionation of hydrogen peroxide into singlet molecular oxygen, 1 O 2 ( 1 Δ g ). The solvents are investigated by resorting to the detection of the infra-red luminescence of 1 O 2 at 1270 nm. Preparative peroxidations of representative substrates are carried out in the most efficient ones. The latter are protic and polar and constitute a simpler alternative to the well suited but more intricate microemulsion systems for the peroxidation of hydrophobic substrates with chemically generated 1 O 2 .

The unexpected role of pyridine-2-carboxylic acid in manganese based oxidation catalysis with pyridin-2-yl based ligands

A number of manganese-based catalysts employing ligands whose structures incorporate pyridyl groups have been reported previously to achieve both high turnover numbers and selectivity in the oxidation of alkenes and alcohols, using H(2)O(2) as terminal oxidant. Here we report our recent finding that these ligands decompose in situ to pyridine-2-carboxylic acid and its derivatives, in the presence of a manganese source, H(2)O(2) and a base. Importantly, the decomposition occurs prior to the onset of catalysed oxidation of organic substrates. It is found that the pyridine-2-carboxylic acid formed, together with a manganese source, provides for the observed catalytic activity. The degradation of this series of pyridyl ligands to pyridine-2-carboxylic acid under reaction conditions is demonstrated by (1)H NMR spectroscopy. In all cases the activity and selectivity of the manganese/pyridyl containing ligand systems are identical to that observed with the corresponding number of equivalents of pyridine-2-carboxylic acid; except that, when pyridine-2-carboxylic acid is used directly, a lag phase is not observed and the efficiency in terms of the number of equivalents of H(2)O(2) required decreases from 6-8 equiv. with the pyridin-2-yl based ligands to 1-1.5 equiv. with pyridine-2-carboxylic acid.

Manganese catalyzed cis-dihydroxylation of electron deficient alkenes with H2O2

A practical method for the multigram scale selective cis-dihydroxylation of electron deficient alkenes such as diethyl fumarate and N-alkyl and N-aryl-maleimides using H(2)O(2) is described. High turnovers (>1000) can be achieved with this efficient manganese based catalyst system, prepared in situ from a manganese salt, pyridine-2-carboxylic acid, a ketone and a base, under ambient conditions. Under optimized conditions, for diethyl fumarate at least 1000 turnovers could be achieved with only 1.5 equiv. of H(2)O(2) with d/l-diethyl tartrate (cis-diol product) as the sole product. For electron rich alkenes, such as cis-cyclooctene, this catalyst provides for efficient epoxidation.

Palladium-Catalyzed Selective Anti-Markovnikov Oxidation of Allylic Esters†

The palladium(II)-catalyzed oxidation of alkenes to carbonyl compounds, usually referred to as the Wacker or Wacker– Tsuji reaction, is arguably one of the best-known reactions catalyzed by palladium. It is an important catalytic process industrially, for the production of ethanal, and synthetically, for the conversion of olefins to ketones. The oxidation of terminal alkenes typically proceeds with selective formation of methylketones. The anti-Markovnikov (AM) Wacker oxidation of terminal olefins to aldehydes remains, however, a major challenge. Under certain conditions, AM selectivity is obtained with styrenes, Michael-type acceptor alkenes and certain olefins, such as 2-vinyl-furanosides, bearing a directing functional group. Indeed, high aldehyde selectivity in the catalytic oxidation of phthalimide-protected allylic amines was reported by our group to yield a key intermediate in the preparation of b-amino acids. On the other hand, Sigman and co-workers have reported the regioselective oxidation of protected allylic amines controlled by various palladium catalysts to yield the corresponding methyl ketones. In 1986, Pd-catalyzed aldehyde selective oxidation of styrene with O2 and CuCl in tBuOH at 30 8C was reported by Feringa. Later, Wenzel reported good selectivity (6:1) for aldehyde formation from allyl acetate (56% combined yield of aldehyde and ketone), in tBuOHwith PdCl2/CH3CN/CuCl/ NaCl at 50 8C. More recently, the aldehyde-selective oxidation of styrenes was reported by Grubbs and co-workers using the catalyst [PdCl2(CH3CN)2], p-benzoquinone as oxidant, and tBuOH as solvent at 85 8C. However, a more general anti-Markovnikov alkene oxidation of non-aryl alkenes under mild conditions remains a challenge, despite the tremendous value in extending this reaction to other substrate classes, in particular allylic alcohols and esters. b-Hydroxy aldehydes are usually prepared by the crossaldol reaction between aldehydes or an aldehyde and a ketone. The direct catalytic formation of an aldehyde by selective attack at the terminal carbon of an a-olefin would be a highly valuable alternative. However, the selective antiMarkovnikov oxidation of allylic alcohols into b-hydroxy aldehydes has proven to be very difficult owing to formation of the ketone products and competing olefin isomerization. Herein, we demonstrate the aldehyde-selective catalytic oxidation of ester-protected allylic alcohols with as low as 0.5 mol% of [PdCl2(PhCN)2] and p-benzoquinone (BQ) as oxidant in tBuOH under ambient conditions. Importantly, the same anti-Markovnikov oxidation products were obtained selectively from both branched and linear allylic esters (Scheme 1), owing to rapid isomerization between allylic esters under the reaction conditions (see below).

Manganese-Catalyzed Selective Oxidation of Aliphatic C-H groups and Secondary Alcohols to Ketones with Hydrogen Peroxide

An efficient and simple method for selective oxidation of secondary alcohols and oxidation of alkanes to ketones is reported. An in situ prepared catalyst is employed based on manganese(II) salts, pyridine-2-carboxylic acid, and butanedione, which provides good-to-excellent conversions and yields with high turnover numbers (up to 10 000) with H2 O2 as oxidant at ambient temperatures. In substrates bearing multiple alcohol groups, secondary alcohols are converted to ketones selectively and, in general, benzyl C-H oxidation proceeds in preference to aliphatic C-H oxidation.

Effect of additives on chemoselectivity and diastereoselectivity in the catalytic epoxidation of chiral allylic alcohols with hydrogen peroxide and binuclear manganese complexes.

The catalytic oxidations of chiral allylic alcohols 2 by manganese complexes of the cyclic triamine 1,4,7-trimethyl-1,4,7-triazacyclononane (tmtacn) 1 and hydrogen peroxide as oxygen donor in the presence of co-catalyst are investigated to understand the factors that affect the catalyst selectivity. Chemoselectivity and diastereoselectivity of catalyst 1 are significantly affected by the structure of the allylic alcohol and the nature and amount of co-catalyst. More pronounced is the influence of the amount of added molar equivalents of H(2)O(2) (20-110 mol % with respect to the substrate). Our present results reflect the complex redox chemistry of the Mn catalyst 1/H(2)O(2)/co-catalyst system in the early phase of the alkene oxidation.

“Dark” Singlet Oxygenation of Hydrophobic Substrates in Environmentally Friendly Microemulsions

The molybdate-catalyzed “dark” singlet oxygenation of hydrophobic compounds with hydrogen peroxide proceeds efficiently with low catalyst loadings (10 –3 mol %) in chlorine-free w/o microemulsions. These micro-heterogeneous systems are composed of sodium dodecyl sulfate (SDS)/n-butanol/water/organic phase, the latter being either a ”green” solvent such as ethyl acetate or a liquid substrate, such as α-terpinene or β-citronellol. Very high reactor yields with improved product/SDS ratio can be obtained for the ”dark” singlet oxygenation of such liquid substrates.