Highly Diastereoselective Preparation of Tertiary Alkyl Thiocyanates en Route to Thiols by Stereoinvertive Nucleophilic Substitution at Nonclassical Carbocations

Patel, Kaushalendra; Oginetz, Lior; Marek, Ilan

doi:10.1021/acs.orglett.3c03396

Cited by 5 publications

(4 citation statements)

References 41 publications

(56 reference statements)

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“…[35] Upon treating stereodefined cyclopropane 40 with a catalytic amount of Lewis acid, the addition of a nucleophile yields homoallyl product 42, with a complete inversion of configuration at the β-quaternary center (the αcenter is converted into an alkene). This transformation can be conducted with a wide variety of nucleophiles, including alkyls, [36] alcohols, [38] carboxylates, [35] halogens, [35] nitrogen [38] and sulfur [39] based nucleophiles. Moreover, this transformation can be extended to the preparation of acyclic products with high enantioselectivity.…”

Section: σ Bond Participationmentioning

confidence: 99%

Stereoinvertive S_N1 Through Neighboring Group Participation

Suresh,

Orbach,

Marek

2024

Angewandte Chemie

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Neighboring group participation, the assistance of non‐conjugated electrons to a reaction center, is a fundamental phenomenon in chemistry. In the framework of nucleophilic substitution reactions, neighboring group participation is known to cause rate acceleration, first order kinetics (SN1), and retention of configuration. The latter phenomenon is a result of double inversion: the first one when the neighboring group displaces the leaving group, and the second when a nucleophile substitutes the neighboring group. This powerful control of stereoretention has been widely used in organic synthesis for more than a century. However, neighboring group participation may also lead to inversion of configuration, a phenomenon which is often overlooked. Herein, we review this unique mode of stereoinversion, dividing the relevant reactions into three classes with the aim to introduce a fresh perspective on the different modes of stereoinversion via neighboring group participation as well as the factors that control this stereochemical outcome.

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Section: σ Bond Participationmentioning

confidence: 99%

Stereoinvertive S_N1 Through Neighboring Group Participation

Suresh,

Orbach,

Marek

2024

Angewandte Chemie

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“…For instance, Feringa, Houk and Fujita reported in 2018 that cycloheptenyl bromide III undergoes an enantiospecific rearrangement to its cyclohexenyl derivative IV under Lewis acid catalysis, a process that involves CPC cation V . Similarly, Marek has published a series of reports starting in 2020, discussing how cyclopropylcarbinols VI form homoallylic products VII with high diastereoselectivity, as long as no aromatic substituent is located at the R 3 or R 4 positions. − Our group studied this system computationally and showed that CPC intermediate VIII is responsible for the observed selectivity . This cation only rearranges faster than nucleophilic trapping when R 3 is an aryl substituent, which enables a classical homoallylic cation to intervene, leading to reduced specificity.…”

Section: Introductionmentioning

confidence: 99%

Substituent Effects on the Equilibria between Cyclopropylcarbinyl, Bicyclobutonium, Homoallyl, and Cyclobutyl Cations

Larmore,

Champagne

2024

J. Org. Chem.

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The cyclopropylcarbinyl (CPC) and bicyclobutonium (BCB) structures of the C 4 H 7 + cation have been proposed as intermediates in various reactions forming cyclopropylcarbinyl, cyclobutyl, or homoallyl products. While these cations can react with nucleophiles stereospecifically, in each system there are usually multiple BCB/CPC cations in equilibrium with related cyclobutyl (CB) and homoallyl (HA) cations, from which stereospecificity is jeopardized. Using density functional theory (DFT) and DLPNO−CCSD(T) calculations, we studied the electronic and steric effects on the equilibria between mono-and polysubstituted C 4 H 7 + cations. We find that the shapes of the potential energy surfaces (PESs) vary significantly, with structures that are minima for a given substituent becoming high-energy transition structures for another. Electron-donating groups at C1, C2, or C3/C4 positions favor CPC, BCB/CB, and HA structures, respectively. Electron-withdrawing groups yield shallower PESs where multiple related structures are energetically accessible. Strong Hammett correlations (σ + ) are observed for the substituent effects, which appear to be additive. In addition, BCB cations with more substituents are energetically destabilized compared to CPC cations, except with donating substituents at the C2 position. This work allows predictions of the major structures expected in mixtures of CPC/BCB/ CB/HA cations for given substituent patterns, and of the major products produced from such cations.

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“…Therefore, the development of efficient methodologies for synthesizing stereogenic fluorinated building blocks remains an important objective in organic chemistry . Inspired by previous results from our group in controlling the stereochemistry of S N 1 reactions involving nonclassical carbocations (Scheme b), we wondered whether we could employ a similar strategy to prepare acyclic molecular backbones containing the CF 3 groups with adjacent stereocenters, alongside additional halogens, including fluorine (Scheme c). Indeed, we have recently reported that cyclopropyl carbinol derivatives 1 featuring a quaternary carbon stereocenter at C 4 undergo a smooth Lewis acid-catalyzed ring opening, resulting in the formation of the nonclassical cyclopropylcarbinyl carbocation intermediate CPC .…”

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Stereoselective Nucleophilic Halogenation at CF₃-Substituted Nonclassical Carbocation

Myronova,

Cahard,

Marek

2024

Org. Lett.

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CF 3 -substituted cyclopropyl carbinol derivatives undergo regioselective and diastereoselective nucleophilic halogenation at the quaternary carbon center to provide acyclic products as a single diastereomer. The selectivity of the substitution is rationalized by the formation of a nonclassical cyclopropylcarbinyl cation intermediate, reacting at the most-substituted carbon center. Tertiary alkyl chlorides, bromides, and fluorides adjacent to a stereogenic C−CF 3 -motif are diastereomerically pure and can be obtained in few catalytic steps from commercially available alkynes.

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Highly Diastereoselective Preparation of Tertiary Alkyl Thiocyanates en Route to Thiols by Stereoinvertive Nucleophilic Substitution at Nonclassical Carbocations

Cited by 5 publications

References 41 publications

Stereoinvertive S_N1 Through Neighboring Group Participation

Stereoinvertive S_N1 Through Neighboring Group Participation

Substituent Effects on the Equilibria between Cyclopropylcarbinyl, Bicyclobutonium, Homoallyl, and Cyclobutyl Cations

Stereoselective Nucleophilic Halogenation at CF₃-Substituted Nonclassical Carbocation

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Highly Diastereoselective Preparation of Tertiary Alkyl Thiocyanates en Route to Thiols by Stereoinvertive Nucleophilic Substitution at Nonclassical Carbocations

Cited by 5 publications

References 41 publications

Stereoinvertive SN1 Through Neighboring Group Participation

Stereoinvertive SN1 Through Neighboring Group Participation

Substituent Effects on the Equilibria between Cyclopropylcarbinyl, Bicyclobutonium, Homoallyl, and Cyclobutyl Cations

Stereoselective Nucleophilic Halogenation at CF3-Substituted Nonclassical Carbocation

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Stereoinvertive S_N1 Through Neighboring Group Participation

Stereoinvertive S_N1 Through Neighboring Group Participation

Stereoselective Nucleophilic Halogenation at CF₃-Substituted Nonclassical Carbocation