Iron Catalyst enantioselective

The comparison of a bis(imino)pyridine iron complex and a pyridine bis (oxazoline) iron complex in hydrosilylation reactions is shown in Scheme 24 [73]. Both iron complexes showed efficient activity at 23°C and low to modest enantioselectivites. However, the steric hindered acetophenone derivatives such as 2, 4, 6 -trimethylacetophenone and 4 -ferf-butyl-2, 6 -dimethylacetophenone reacted sluggishly. The yields and enantioselectivities increased slightly when a combination of iron catalyst and B(CeF5)3 as an additive was used. 

In the past, this field has been dominated by ruthenium, rhodium and iridium catalysts with extraordinary activities and furthermore superior enantioselectivities however, some investigations were carried out with iron catalysts. Early efforts were reported on the successful use of hydridocarbonyliron complexes HFcm(CO) as reducing reagent for a, P-unsaturated carbonyl compounds, dienes and C=N double bonds, albeit complexes were used in stoichiometric amounts [7]. The first catalytic approach was presented by Marko et al. on the reduction of acetone in the presence of Fe3(CO)12 or Fe(CO)5 [8]. In this reaction, the hydrogen is delivered by water under more drastic reaction conditions (100 bar, 100 °C). Addition of NEt3 as co-catalyst was necessary to obtain reasonable yields. The authors assumed a reaction of Fe(CO)5 with hydroxide ions to yield H Fe(CO)4 with liberation of carbon dioxide since basic conditions are present and exclude the formation of molecular hydrogen via the water gas shift reaction. H Fe(CO)4 is believed to be the active catalyst, which transfers the hydride to the acceptor. The catalyst presented displayed activity in the reduction of several ketones and aldehydes (Scheme 4.1) [9]. 

More recently, Chen et al. reported an asymmetric transfer hydrogenation (Scheme 4.3) based on [Et3NH][HFe3(CO)11] and chelating chiral ligands [11], In the presence of enantiopure diaminodiphosphine iron catalysts they claimed good conversion and enantioselectivity up to 98% ee (substrate 5j). 

It was found that the iron catalysts prepared in situ from FeCl -dH O and chiral Spiro bisoxazoline ligands 23 exhibited excellent enantioselectivity as well as reactivity for the insertion of O—H bonds of various saturated alcohols and allylic alcohols (Scheme 46) [111]. The catalyst Fe-(S, S,S)-23c showed higher yields and higher enantioselectivities than any other metal catalysts. 

Scheme 6a. Diversity-based approach to iron-based enantioselective catalysts - the ligand library used for catalyst discovery.

Polymer RuCO-porphyrins 102 and 103 (Scheme 48) were used for the cyclopropanation reaction of styrenes but they were also tested in the epoxidation reaction. Contrary to cyclopropanation for which moderate enantioselectivities and low activities were observed, these Ru porphyrin complexes gave good ee (up to 76%) and activity (up to 89%) for AE of unfimctionalized olefines [204], Recently, Simmoneaux showed that iron catalyst 326 derived from electropolymerized tetraspirofluorenyl porphyrin (Scheme 138) led to moderate yields without chiral induction [205],... 

Chiral iron catalysts form a relatively new type of catalysts for asymmetric cyclopropanation. The first reported catalysts derived from chiral tetraaza macrocycles gave moderate enantioselectivities (up to 79% ee) but good diastere-oselectivities t/c — 13.3 1) (95). With the use of a chiral porphyrin catalyst (23b when M = Fe, X = Cl in Scheme 15), improvements in the enantioselective cyclopropanation from styrene and EDA was observed, with high turnover of more than 1200, 86% ee and high trans-selectivity t/c of 23 1) (96). Other types of iron catalysts derived from chiral terpyridines were also found to catalyze asymmetric cyclopropanation. After reacting with AgOTf, [Fe(14)Cl2] (14, R = re-Bu in Scheme 11) gave 67% ee of the same cyclopropane (97). 

Scheme 3 Enantioselective a-azidation via productive merger of iodine(in) reagents with iron catalysts...

Employment of chiral bis(oxazolinylphenyl)amines such as SJS)-BopsL-dpm (Scheme 4-328) as ligands for iron catalysts leads to almost quantitative yields and high enantioselectivities for the asymmetric hydrosilylation of ketones and asymmetric conjugate hydrosilylation of enones with (diethoxy)methylsilane as reductant (Scheme 4-329). Both enantiomers of the hydrosilylation product can be obtained from the same chiral ligand by a slight variation of the reaction conditions. The mixed catalyst system of (S -Bopa-dpm and iron(II) acetate provides the (/ )-enantiomer of the alcohol... 

We employed malononitrile and l-crotonoyl-3,5-dimethylpyrazole as donor and acceptor molecules, respectively. We have found that this reaction at room temperature in chloroform can be effectively catalyzed by the J ,J -DBFOX/Ph-nick-el(II) and -zinc(II) complexes in the absence of Lewis bases leading to l-(4,4-dicya-no-3-methylbutanoyl)-3,5-dimethylpyrazole in a good chemical yield and enantio-selectivity (Scheme 7.47). However, copper(II), iron(II), and titanium complexes were not effective at all, either the catalytic activity or the enantioselectivity being not sufficient. With the J ,J -DBFOX/Ph-nickel(II) aqua complex in hand as the most reactive catalyst, we then investigated the double activation method by using this catalyst. 

Ligands of type 48 were synthesized by the cyclization reaction of diamines with dithioaldehydes. Iron complexes formed with those structures led, however, to active but weakly enantioselective catalysts. The best results were... 

Dioxo-ruthenium porphyrin (19) undergoes epoxidation.69 Alternatively, the complex (19) serves as the catalyst for epoxidation in the presence of pyridine A-oxide derivatives.61 It has been proposed that, under these conditions, a nms-A-oxide-coordinated (TMP)Ru(O) intermediate (20) is generated, and it rapidly epoxidizes olefins prior to its conversion to (19) (Scheme 8).61 In accordance with this proposal, the enantioselectivity of chiral dioxo ruthenium-catalyzed epoxidation is dependent on the oxidant used.55,61 In the iron porphyrin-catalyzed oxidation, an iron porphyrin-iodosylbenzene adduct has also been suggested as the active species.70... 

Metal complexes of bis(oxazoline) ligands are excellent catalysts for the enantioselective Diels-Alder reaction of cyclopentadiene and 3-acryloyl-l,3-oxa-zolidin-2-one. This reaction was most commonly utilized for initial investigation of the catalytic system. The selectivity in this reaction can be twofold. Approach of the dienophile (in this case, 3-acryloyl-l,3-oxazolidin-2-one) can be from the endo or exo face and the orientation of the oxazolidinone ring can lead to formation of either enantiomer R or S) on each face. The ideal catalyst would offer control over both of these factors leading to reaction at exclusively one face (endo or exo) and yielding exclusively one enantiomer. Corey and co-workers first experimented with the use of bis(oxazoline)-metal complexes as catalysts in the Diels-Alder reaction between cyclopentadiene 68 and 3-acryloyl-l,3-oxazolidin-2-one 69 the results are summarized in Table 9.7 (Fig. 9.20). For this reaction, 10 mol% of various iron(III)-phe-box 6 complexes were utilized at a reaction temperature of —50 °C for 2-15 h. The yields of cycloadducts were 85%. The best selectivities were observed when iron(III) chloride was used as the metal source and the reaction was stirred at —50 °C for 15 h. Under these conditions the facial selectivity was determined to be 99 1 (endo/exo) with an endo ee of 84%. 

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