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Alkylation of β-Ketoester Enolates: Acetoacetic Ester Synthesis01:07

Alkylation of β-Ketoester Enolates: Acetoacetic Ester Synthesis

Acetoacetic ester synthesis is a method to obtain ketones from alkyl halides and β-keto esters. The reaction occurs in the presence of an alkoxide base that abstracts the acidic proton of the β-keto esters. The step results in an enolate ion which is doubly stabilized. The enolate then reacts with an alkyl halide via the SN2 process to produce an alkylated ester intermediate with a new C–C bond. The hydrolysis of the intermediate, followed by acidification, results in an alkylated β-keto acid.
Alkylation of β-Diester Enolates: Malonic Ester Synthesis01:14

Alkylation of β-Diester Enolates: Malonic Ester Synthesis

Malonic ester synthesis is a method to obtain α substituted carboxylic acids from ꞵ-diesters such as diethyl malonate and alkyl halides.
Reactivity of Enols01:18

Reactivity of Enols

Enols are a class of compounds where a hydroxyl group is attached to a carbon–carbon double bond, which implies that it is a vinyl alcohol. A carbonyl compound with an α hydrogen undergoes keto–enol tautomerism and remains in equilibrium with its tautomer, the enol form. Usually, the keto tautomer is present in a higher concentration than the enol tautomer due to the higher bond energy of C=O compared to C=C. Moreover, the direction of the keto–enol equilibrium is governed by factors like...
Aldehydes and Ketones with Amines: Imine Formation Mechanism01:23

Aldehydes and Ketones with Amines: Imine Formation Mechanism

Imine formation involves the addition of carbonyl compounds to a primary amine. It begins with the generation of carbinolamine through a series of steps involving an initial nucleophilic attack and then several proton transfer reactions. The second part includes the elimination of water, as a leaving group, to give the imine.
Imines are formed under mildly acidic conditions. A pH of 4.5 is ideal for the reaction.
If the pH is low or the solution is too acidic, the reaction slows down in the...
Regioselective Formation of Enolates01:33

Regioselective Formation of Enolates

As depicted in the figure below, the unsymmetrical ketones can form two possible enolates: less substituted or more substituted enolates. Usually, the thermodynamic enolates are formed from the more substituted α-carbon atom, while the kinetic enolates are formed faster by deprotonation from the less substituted position. The thermodynamic enolates have lower energy, so they are more stable. But the energy required to form kinetic enolates is less.
Stereochemical Effects of Enolization01:12

Stereochemical Effects of Enolization

The chiral α-carbon of the carbonyl compound is the stereocenter of the molecule. As shown in the figure below, when such a carbonyl compound undergoes racemization under an acidic or basic condition, an achiral enol is formed.

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Related Experiment Video

Updated: Jun 1, 2026

A Strategy for Sensitive, Large Scale Quantitative Metabolomics
14:18

A Strategy for Sensitive, Large Scale Quantitative Metabolomics

Published on: May 27, 2014

Ethyl (2E)-2-(hydroxy-imino)propanoate.

Igor Vasyl Nikolayenko, Carla Bazzicalupi, Gayle Pamela Thubron

    Acta Crystallographica. Section E, Structure Reports Online
    |May 18, 2011
    PubMed
    Summary

    This study reveals the planar structure of a C(5)H(9)NO(3) molecule, stabilized by π-conjugation and confirmed by DFT calculations. Molecular sheets form through hydrogen bonding and π-stacking, creating a unique crystal structure.

    Area of Science:

    • Crystallography
    • Computational Chemistry
    • Molecular Structure

    Background:

    • Understanding molecular planarity and crystal packing is crucial for predicting material properties.
    • The interplay of electronic conjugation and intermolecular forces dictates solid-state arrangements.
    • Oxime and carbonyl groups are common functional groups with significant electronic interactions.

    Purpose of the Study:

    • To determine the crystal structure and molecular geometry of the title compound C(5)H(9)NO(3).
    • To investigate the factors influencing molecular planarity and crystal packing.
    • To computationally confirm the preferred electronic conformation.

    Main Methods:

    • Single crystal X-ray diffraction analysis.
    • Ab initio calculations using Density Functional Theory (DFT) at the B3LYP/6-311G**++ level.

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    A Two-Step Protocol for Umpolung Functionalization of Ketones Via Enolonium Species

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    Facile Preparation of (2Z,4E)-Dienamides by the Olefination of Electron-deficient Alkenes with Allyl Acetate
    06:46

    Facile Preparation of (2Z,4E)-Dienamides by the Olefination of Electron-deficient Alkenes with Allyl Acetate

    Published on: June 21, 2017

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    Last Updated: Jun 1, 2026

    A Strategy for Sensitive, Large Scale Quantitative Metabolomics
    14:18

    A Strategy for Sensitive, Large Scale Quantitative Metabolomics

    Published on: May 27, 2014

    A Two-Step Protocol for Umpolung Functionalization of Ketones Via Enolonium Species
    08:12

    A Two-Step Protocol for Umpolung Functionalization of Ketones Via Enolonium Species

    Published on: August 16, 2018

    Facile Preparation of (2Z,4E)-Dienamides by the Olefination of Electron-deficient Alkenes with Allyl Acetate
    06:46

    Facile Preparation of (2Z,4E)-Dienamides by the Olefination of Electron-deficient Alkenes with Allyl Acetate

    Published on: June 21, 2017

  • Analysis of intermolecular interactions including hydrogen bonding and π-stacking.
  • Main Results:

    • The molecule C(5)H(9)NO(3) exhibits a nearly planar geometry due to π-conjugation between hydroxy-imino and carbonyl groups.
    • The E conformer was computationally confirmed as the lowest energy state.
    • Crystal structure features infinite molecular sheets formed by O-H⋯N hydrogen bonds and π-stacking, with molecules arranged in a herringbone pattern.

    Conclusions:

    • The planar nature and specific arrangement of C(5)H(9)NO(3) molecules are governed by electronic conjugation and intermolecular forces.
    • The observed crystal packing, characterized by molecular sheets and herringbone arrangement, results from a combination of hydrogen bonding and π-stacking.
    • The study provides insights into the structure-property relationships of molecules with oxime and carbonyl functionalities.