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Related Concept Videos

E2 Reaction: Stereochemistry and Regiochemistry02:43

E2 Reaction: Stereochemistry and Regiochemistry

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Elimination reactions of alkyl halides can yield one or more alkenes depending on the specific regiochemical and stereochemical considerations. While the regiochemistry of the reaction governs the location of the double bond in the product, the stereochemical requirements often influence the geometry.
When a substrate with two different β hydrogens undergoes an E2 elimination, the presence of a strong base can yield two regioisomeric alkenes. The more-substituted alkene is the major...
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E1 Reaction: Stereochemistry and Regiochemistry02:43

E1 Reaction: Stereochemistry and Regiochemistry

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One of the critical aspects of the E1 reaction mechanism, as also observed in E2, is the regiochemistry, with multiple regioisomers obtained as products. In the example discussed, the presence of water as a weak base favors elimination over substitution to generate two alkenes. Given that alkenes’ stability increases with the number of alkyl groups across the double bond, typically, E1 reactions lead to the Zaitsev product, for this is more substituted and stable than the Hofmann product.
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SN2 Reaction: Stereochemistry02:23

SN2 Reaction: Stereochemistry

11.6K
In an SN2 reaction, the nucleophilic attack on the substrate and departure of the leaving group occurs simultaneously through a transition state. As the nucleophile approaches the substrate from the back-side, the configuration of the substrate carbon changes from tetrahedral to trigonal bipyramidal and then back to tetrahedral, leading to an inversion in the configuration of the product.
If the substrate is an achiral molecule at the α-carbon, the inversion of configuration is not...
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Photochemical Electrocyclic Reactions: Stereochemistry01:26

Photochemical Electrocyclic Reactions: Stereochemistry

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The absorption of UV–visible light by conjugated systems causes the promotion of an electron from the ground state to the excited state. Consequently, photochemical electrocyclic reactions proceed via the excited-state HOMO rather than the ground-state HOMO. Since the ground- and excited-state HOMOs have different symmetries, the stereochemical outcome of electrocyclic reactions depends on the mode of activation; i.e., thermal or photochemical.
Selection Rules: Photochemical Activation
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Thermal Electrocyclic Reactions: Stereochemistry01:17

Thermal Electrocyclic Reactions: Stereochemistry

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The stereochemistry of electrocyclic reactions is strongly influenced by the orbital symmetry of the polyene HOMO. Under thermal conditions, the reaction proceeds via the ground-state HOMO.
Selection Rules: Thermal Activation
Conjugated systems containing an even number of π-electron pairs undergo a conrotatory ring closure. For example, thermal electrocyclization of (2E,4E)-2,4-hexadiene, a conjugated diene containing two π-electron pairs, gives trans-3,4-dimethylcyclobutene.
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SN1 Reaction: Stereochemistry02:15

SN1 Reaction: Stereochemistry

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This lesson provides an in-depth discussion of the stereochemical outcomes in an SN1 reaction.
In the first step of an SN1 reaction, the bond between the electrophilic carbon and the leaving group ionizes to generate the carbocation intermediate. The second step of the mechanism is the nucleophilic attack.
In the formed carbocation, the positively charged carbon is sp2 hybridized with a trigonal planar geometry. As all the three substituents lie on the same plane, a plane of symmetry for the...
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Stereo-reversed E2 unlocks Z-selective C-H functionalization.

Peter J Verardi1, Elizabeth A Ryutov1, Poulami Mukherjee2

  • 1Department of Chemistry, University of Wisconsin-Madison, 1101 University Avenue, Madison, WI, USA.

Science (New York, N.Y.)
|September 18, 2025
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Summary

Researchers developed a new method for Z-selective alkene synthesis using paired electrolysis to create bis-sulfonium intermediates. This approach overcomes challenges in C-H activation, enabling efficient access to valuable Z-alkene compounds.

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Area of Science:

  • Organic Chemistry
  • Synthetic Chemistry
  • Catalysis

Background:

  • Stereoselective functionalization of C-H bonds is a significant challenge in organic synthesis.
  • Existing C-H activation methods struggle with Z-selective alkene synthesis, especially for terminal alkenes.
  • Selective cleavage of hindered C-H bonds in terminal alkenes remains difficult.

Purpose of the Study:

  • To develop a novel method for Z-selective functionalization of alkenes.
  • To overcome limitations in current C-H activation strategies for Z-alkene synthesis.
  • To provide efficient access to Z-alkene targets from simple starting materials.

Main Methods:

  • Transformation of alkenes into transient 1,2-bis-sulfonium intermediates.
  • Utilizing paired electrolysis for selective generation and in situ elimination of bis-sulfonium intermediates.
  • Employing Z-selective elimination of bis-sulfonium intermediates, challenging conventional E2 stereoselectivity.

Main Results:

  • Successful Z-selective elimination of 1,2-bis-sulfonium intermediates was achieved.
  • Paired electrolysis enabled efficient in situ generation and elimination of the intermediates.
  • The method provides access to Z-alkenyl sulfonium linchpins, key precursors for Z-alkenes.
  • The developed strategy offers a new route to diverse Z-alkene targets via cross-coupling.

Conclusions:

  • A novel strategy for Z-selective alkene synthesis has been established.
  • Paired electrolysis is identified as a key enabling technology for this transformation.
  • The method offers a robust and efficient pathway to valuable Z-alkene compounds from readily available feedstocks.