Asymmetric exchange of cyclopalladated ligands: A new route to optically active phosphapalladacycles

Dunina, V. V.; Gorunova, O. N.; Kuznetsova, E. D.; Turubanova, Eugeniya I.; Ливанцов, М. В.; Grishin, Yuri K.; Кузьмина, Л. Г.; Churakov, Andrei V.

doi:10.1007/s11172-006-0573-8

Cited by 11 publications

(3 citation statements)

References 70 publications

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“…31 P NMR (δ, 400 MHz, CDCl 3 ): 33.29. MS (m/z, EI): 754 (4%), 755 (6), 756 (25), 757 (64), 758 (100), 759 (74), 760 (64), 761 (60), 762 (38), 763 (28), 764 (10), 765 (2).…”

Section: Methodsmentioning

confidence: 99%

“…The majority of scalemic planar chiral palladacycles are obtained by resolution or by the use of a chiral auxiliary to control diastereoselective palladadation, the synthesis of 1 and 2 falling into this latter category. , In contrast, examples of enantioselective palladation are rare. One of us recently reported the application of 1a as a reagent for the transcyclopalladation of prochiral ferrocenes 3 , resulting in the highly enantioselective generation of phosphapalladacycles 4 (Scheme ). , In 1979 Sokolov and others described the reaction of (dimethylaminomethyl)ferrocene ( 5 ) with sodium tetrachloropalladate together with 1 equiv of ( S )- N -acetylleucine ( 7a ), which resulted in the isolation of palladacycle 6 in up to 79% ee (Scheme ) . There is currently a great deal of interest in transition-metal C−H activation chemistry and its application to arene substitution, including enantioselective functionalization .…”

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confidence: 99%

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Synthesis of Planar Chiral Phosphapalladacycles by N-Acyl Amino Acid Mediated Enantioselective Palladation

Günay

Richards

2009

Organometallics

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Hydrolysis of scalemic trichloroacetamides Cl3CCONHCH(R)CHCH2 and allylation, or acylation with but-3-enoic acid, followed by ring-closing metathesis resulted in the formation of unsaturated pyrrolidine and piperidine building blocks. These were employed in the synthesis of (S)-coniine (R = Pr) and a formal synthesis of (+)-anisomycin (R = p-MeOC6H4). Extension of this methodology with R = CH2CHCH2 employing two ring-closing metatheses resulted in the synthesis of unsaturated quinolizidinone and indolizidinone frameworks

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“…31 P NMR (δ, 400 MHz, CDCl 3 ): 33.29. MS (m/z, EI): 754 (4%), 755 (6), 756 (25), 757 (64), 758 (100), 759 (74), 760 (64), 761 (60), 762 (38), 763 (28), 764 (10), 765 (2).…”

Section: Methodsmentioning

confidence: 99%

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confidence: 99%

Synthesis of Planar Chiral Phosphapalladacycles by N-Acyl Amino Acid Mediated Enantioselective Palladation

Günay

Richards

2009

Organometallics

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“…The fixing of planar chirality onto the ferrocene framework demands appropriate chiral control, through either an existing internal stereogenic center or an external chiral auxiliary. Previous reports by Dunina adopted Pd(OAc) 2 and cyclopalladated ligand exchange (CLE) as primary means to consummate a ferrocenyl P–C-ligated palladium(II) complex. Although palladation attempts via Pd(OAc) 2 and CLE generated the targeted palladated product within 3 h, poor yields of 20% and 10% were obtained, respectively.…”

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Asymmetric Construction of a Ferrocenyl Phosphapalladacycle from Achiral Enones and a Demonstration of Its Catalytic Potential

Gan

Sadeer

et al. 2014

Organometallics

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A new approach toward ferrocenyl phosphapalladacycle construction from achiral enones via asymmetric hydrophosphination and subsequent diastereoselective C−H activation is described. Its catalytic efficacy toward C−C bond formation is subsequently illustrated. F errocenyl phosphines incorporating central and planar chirality elements have a proven track record as powerful auxiliaries in asymmetric synthesis. 1 As a result, extensive efforts have been invested in their challenging synthesis. 2 These pursuits focused on the development of ferrocenyl diphosphine and phosphapalladacyclic systems, which contain both the aforementioned stereogenic components on the same molecule. The synthesis of ferrocenyl phosphapalladacycles generally comprises two steps, i.e, (i) the formation of a C-chiral monophosphine and (ii) subsequent palladation via C−H/C− Br activation. There are a couple of traditional approaches by which the former may be achieved, either through enantioselective 3 /diastereoselective 4 lithiation controlled by pre-existing chiral element(s) or secondary phosphine substitution of an enantiopure Ugi amine derivative. 5 Both these methods although highly selective and synthetically relevant are, however, limited by the necessity of employing an enantiopure substrate. The desired ferrocenyl phosphapalladacycle may then be secured by either diastereotopic C−H activation 6 or oxidative addition of palladium(0). 7 A hitherto unexplored route for the enantioselective formation of monoferrocenyl phosphines is the palladiumcatalyzed asymmetric hydrophosphination (AHP) reaction. The emergence of AHP of activated alkenes affording high yields, short reaction times, and excellent selectivities offers an atom-economical yet efficient approach to achieve this goal. 8 However, ferrocenyl-appended substrates have been conspicuously absent from this library. Furthermore, the use of these chiral monophosphine adducts toward the preparation of viable catalysts has rarely been explored. Herein, we report the AHPbased enantioselective construction of a series of C-chiral tertiary ferrocenyl phosphines and the subsequent diastereoselective cyclopalladation of one of the congeners. We began our investigation by screening an array of conditions for the asymmetric addition of diphenylphosphine to 1a catalyzed by (S)-3 (Table 1).During the optimization process, it was evident that while the AHP proceeded smoothly in DCM and MeOH, poor conversions were obtained with THF, acetone, and acetonitrile. Results show a pronounced difference between the performances of the two catalysts (entry 3 vs 4). While the N−C palladacycle (S)-3 catalyzed the reaction within 2 h at RT, its P−C analogue (S)-4 failed to deliver full conversion even after Table 1. Palladacycle-Catalyzed AHP of 1a a entry solvent t (h) yield b (%) ee c (%)

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Metallocyclic Ferrocenyl Ligands

Richards

2009

Chiral Ferrocenes in Asymmetric Catalysis

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This chapter is a comprehensive account of the synthesis and application of planar chiral ferrocene-based metallocycles. The first examples of the asymmetric synthesis of this class of compound date from the late 1970s, with the pioneering work of Viatcheslav Sokolov. However, it is only since the millennium that they have found widespread application, principally as catalysts for the allylic imidate rearrangement initially developed by Larry Overman.In the vast majority of cases the metal of the metallocyclic ring is palladium. Thus this class of compound is a sub-category of palladacycles [1] and/or metallacycles [2] in which the metal is bonded to an sp 2 , or less frequently, an sp 3 carbon atom. A significant feature of anionic bidentate ferrocenyl ligands is that the complexed metal M becomes a direct component of the element of planar chirality displayed by the resultant complex (Scheme 12.1). This contrasts to the majority of neutral bidentate ferrocene ligands [3] (e.g., P-P, P-N etc.), where the complexed metal is more remote from the basis of chirality [4]. Where M ¼ Pd(II) or Pt(II), the ancillary ligands L 1 and L 2 of the resultant square-planar complex are distinguished by the larger trans-influence/effect of the anionic carbon ligand compared to the neutral heteroatom (X) ligand component. This is revealed by the longer L 1 -M bond length compared to the corresponding L 2 -M bond length where L 1 ¼ L 2 1) , and also by analysis of the kinetic and thermodymanic products arising from ligand substitution [5]. The coordination axis perpendicular to the square plane, as represented by diastereotopic ligands L 3 and L 4 , is significantly influenced by the bulk of the metallocene. Thus associative ligand substitution reactions of square-planar complexes will most likely involve approach of the incoming ligand from the top face (L 3 ).

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Asymmetric exchange of cyclopalladated ligands: A new route to optically active phosphapalladacycles

Cited by 11 publications

References 70 publications

Synthesis of Planar Chiral Phosphapalladacycles by N-Acyl Amino Acid Mediated Enantioselective Palladation

Synthesis of Planar Chiral Phosphapalladacycles by N-Acyl Amino Acid Mediated Enantioselective Palladation

Asymmetric Construction of a Ferrocenyl Phosphapalladacycle from Achiral Enones and a Demonstration of Its Catalytic Potential

Metallocyclic Ferrocenyl Ligands

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