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Related Concept Videos

Aromatic Hydrocarbon Anions: Structural Overview01:18

Aromatic Hydrocarbon Anions: Structural Overview

Neutral hydrocarbons like cyclopentadiene with an odd number of carbon atoms and one intervening CH2 group in the ring are not aromatic. Cyclopentadiene with 4 π electrons does not satisfy the 4n + 2 π electron rule. Additionally, the intervening CH2 group is sp3 hybridized and lacks a vacant p orbital, thereby interrupting the overlap of p orbitals in a continuous manner and preventing the delocalization of π electrons throughout the ring.
Due to the absence of continuous overlap of p...
Aromatic Hydrocarbon Cations: Structural Overview01:18

Aromatic Hydrocarbon Cations: Structural Overview

Cycloheptatriene is a neutral monocyclic unsaturated hydrocarbon that consists of an odd number of carbon atoms and an intervening sp3 carbon in the ring. The three double bonds in the ring correspond to 6 π electrons, which is a Huckel number, and therefore satisfies the criteria of 4n + 2 π electrons. However, the intervening sp3 carbon disrupts the continuous overlap of p orbitals. As a result, cycloheptatriene is not aromatic.
Removing one hydrogen from the intervening CH2 group with both...
Basicity of Aliphatic Amines01:21

Basicity of Aliphatic Amines

Amines can behave as Brønsted–Lowry bases by accepting a proton from the acid to form corresponding conjugate acids. Due to a lone pair of nonbonding electrons, aliphatic amines can also act as Lewis bases by forming a covalent bond with an electrophile.
To measure the basicity of amines, two conventions are generally used. The first defines Kb as the basicity constant for the deprotonation reaction of water by the amine, as presented in Figure 1. Conventionally, lower Kb indicates higher...
Basicity of Aromatic Amines01:18

Basicity of Aromatic Amines

The basicity of aromatic amines is much weaker than that of aliphatic amines due to the involvement of the lone pair of electrons over the N atom in resonance with the aryl rings. Generally, the electron-donating ability of any substituents on the aryl ring of aromatic amines increases the basicity of the amine by increasing electron density, and hence the availability of lone pair on the nitrogen. On the other hand, electron-withdrawing functional groups on the aryl ring of amines decrease the...
Diazonium Group Substitution: –OH and –H01:19

Diazonium Group Substitution: –OH and –H

Nitrous acid, a weak acid, is prepared in situ via the reaction of sodium nitrite with a strong acid under cold conditions. This nitrous acid prepared in situ reacts with primary arylamines to form arenediazonium salts. Such reactions are known as diazotization reactions. As shown in Figure 1, the formation of arenediazonium salts begins with the decomposition of nitrous acid in an acidic solution to give nitrosonium ions.
Nucleophilic Aromatic Substitution of Aryldiazonium Salts: Aromatic SN101:14

Nucleophilic Aromatic Substitution of Aryldiazonium Salts: Aromatic SN1

Treating arylamines with nitrous acid gives aryldiazonium salts that are effective substrates in nucleophilic aromatic substitution reactions. The diazonio group in these salts can be easily displaced by different nucleophiles, yielding a wide variety of substituted benzenes. The leaving group departs as nitrogen gas, and this easy elimination is the driving force for the substitution reaction.
In the Sandmeyer reaction, for example, the diazonio group is replaced by a chloro, bromo, or cyano...

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Vibrational Spectra of a N719-Chromophore/Titania Interface from Empirical-Potential Molecular-Dynamics Simulation, Solvated by a Room Temperature Ionic Liquid
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Vibrational Spectra of a N719-Chromophore/Titania Interface from Empirical-Potential Molecular-Dynamics Simulation, Solvated by a Room Temperature Ionic Liquid

Published on: January 25, 2020

Stable aromatic dianion in water.

Elijah Shirman, Alona Ustinov, Netanel Ben-Shitrit

    The Journal of Physical Chemistry. B
    |July 4, 2008
    PubMed
    Summary
    This summary is machine-generated.

    Aromatic dianions derived from perylene diimide (PDI) are stable in water for months, unlike other known dianions. This breakthrough enables new possibilities for aqueous-phase electron transfer systems.

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    Area of Science:

    • Organic Chemistry
    • Materials Science
    • Electrochemistry

    Background:

    • Aromatic dianions are typically unstable in aqueous environments due to facile reaction with water.
    • Perylene diimides (PDIs) are known for their strong optical and electronic properties.

    Discussion:

    • PDIs with polyethylene glycol substituents form a stable aromatic dianion in deoxygenated water via reduction with sodium dithionite.
    • The dianion's stability is attributed to extensive electron delocalization and inherent aromaticity, confirmed by spectroscopic and theoretical analyses.
    • This dianion exhibits reversible redox behavior, reacting with oxygen to regenerate the neutral PDI, which can be re-reduced.

    Key Insights:

    • Discovery of a water-stable aromatic dianion derived from perylene diimide.
    • Demonstration of reversible electron storage and release in aqueous media using PDIs.
    • Identification of factors contributing to dianion stability: electron delocalization and aromatic character.

    Outlook:

    • Potential for developing novel photofunctional materials and electron transfer systems in aqueous phases.
    • Applications in areas requiring controlled electron storage and release, such as rechargeable batteries or sensors.
    • Further research into tuning PDI structures for enhanced stability and performance in aqueous electrochemistry.