Impact of Na− and K−C π-Interactions on the Structure and Binding of M3(sol)n(BINOLate)3Ln Catalysts

Wooten, Alfred J.; Carroll, Patrick J.; Walsh, Patrick J.

doi:10.1021/ol0713234

Cited by 29 publications

(17 citation statements)

References 19 publications

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“…Salvadori reported that YbNaB does not bind water, and related observations were made by Shibasaki and Aspinall . We found that the DMF formyl C–H shifted over 4 ppm in the presence of YbLiB in THF, but no LIS was observed in the presence of RENaB (RE = Yb and Eu) or YbKB under identical conditions . Further insight came from the SC-XRD studies of anhydrous RENaB (RE = La III and Eu III ).…”

Section: Understanding and Expansion Of The Catalysis Of Shibasaki’s ...supporting

confidence: 68%

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Expanding the Rare-Earth Metal BINOLate Catalytic Multitool beyond Enantioselective Organic Synthesis

et al. 2021

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Metrics & MoreArticle Recommendations CONSPECTUS: Shibasaki's rare earth alkali metal BINOLate (REMB) framework has provided chemists with a general catalyst platform to access a range of enantioenriched small molecules from the single, commercially available pro-ligand (R)-or (S)-BINOL. A defining feature of these heterobimetallic frameworks is the high level of catalyst tunability, achieved through the simple modulation of the central rare-earth cation and peripheral alkali metal cations. While this family of multifunctional catalysts displays impressive generality and catalytic capability, detailed mechanistic understanding of these complex, multimetallic systems was lacking prior to our investigations. This backdrop served as initial inspiration for our investigations of this privileged class of complexes over the past decade, which have led to new and exciting advances in catalysis and beyond.In this Account, we describe our investigations using Shibasaki's framework focusing on the central metal-ion, the BINOLate ligands, and the secondary sphere cations. Our studies began with an investigation into the Lewis acidity of the complexes, where we demonstrated that Lewis bases readily coordinate to REMB frameworks when lithium occupies the secondary coordination sphere. This observation was contrasted by the complexes containing sodium or potassium in the secondary coordination sphere, as the rare earth cation is evidently less accessible for substrate binding. Our efforts in understanding the ligand exchange of the complexes enabled the discovery that associative processes dominate the mechanism of ligand exchange and LA/LA (Lewis acid/Lewis acid) and LA/BB (Lewis acid/Brønsted base) catalysis by the REMB frameworks.Replacing metal cations in the secondary coordination sphere with the N,N,N′,N′-tetramethylguanidinium cation delivered an effective precatalyst that is air and water stable over the course of 6 months.To expand the reactivity of the REMB, we investigated the ability of U IV cations to occupy the primary coordination sphere and ZnEt + and Cu(DBU) + cations to occupy the secondary coordination sphere. Synthesizing the REMB complexes using the thiol congener monothioBINOL provided an unusual anionic REMB framework, driven by the oxophilicity of the lithium cations. Using the REMB as a platform for investigating the Ce III /Ce IV redox couple, we demonstrated that, while oxidative cerium functionalization is observed in the case of lithium containing REMBs, salt elimination is observed in the sodium, potassium, and cesium containing REMBs. Furthermore, we found that while the rate of heterogeneous electron transfer for Ce III was k s (Cs I ) > k s (K I ) > k s (Na I ) > k s (Li I ), the rates of reaction with the oxidant trityl chloride trended in the opposite order with k obs (Li I ) ≫ k obs (Na I ) > k obs (K I ) > k obs (Cs I ). We attribute this to the ability to form inner-sphere complexes with the oxidant, rather than differences in redox potential or reorganization energies. Applying our knowle...

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Section: Understanding and Expansion Of The Catalysis Of Shibasaki’s ...supporting

confidence: 68%

Section: Understanding and Expansion Of The Catalysis Of Shibasaki’s ...mentioning

confidence: 99%

Expanding the Rare-Earth Metal BINOLate Catalytic Multitool beyond Enantioselective Organic Synthesis

et al. 2021

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“…Walsh and co-workers elucidated the X-ray crystal structures of Na 3 (THF) in (BINOLate) 3 La and K 3 (THF) n (BINOLate) 3 Yb in which respective Na + •••naphthyl and K + •••naphthyl interactions were observed (Scheme 147c). 409 The authors speculated that these interactions are responsible for the coordination ability of the catalysts, causing the alkali metal dependence of the product stereochemistry. 433 4.1.2.…”

Section: Alkali Metal Cation-assisted Reactionsmentioning

confidence: 99%

Cation−π Interactions in Organic Synthesis

2018

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The cation−π interaction is an attractive noncovalent interaction between a cation and a π system. Due to the stronger interaction energy than those of the other π interactions, such as π–π and CH−π interactions, the cation−π interaction has recently been recognized as a new tool for controlling the regio- and stereoselectivities in various types of organic reactions. This review attempts to cover a variety of organic reactions controlled by cation−π interactions, which includes not only recent examples but also those reported before the term “cation−π interaction” was defined in 1990. This review will provide comprehensive knowledge on the role of cation−π interactions in organic synthesis.

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“…Furthermore, use of molecular sieves as coadditive provided 82% enantioselectivity. On the basis of the control experiments and the previous studies, they speculated that after addition of NaI, an alkali metal exchange would occur to afford a La–Li 2 –Na–L 3 complex, which would slightly modify the asymmetric environment, thereby leading to better results.…”

Section: Additive Effects On Metal-catalyzed Asymmetric Reactionsmentioning

confidence: 99%