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Aldehydes and Ketones with HCN: Cyanohydrin Formation Mechanism01:10

Aldehydes and Ketones with HCN: Cyanohydrin Formation Mechanism

3.4K
Cyanohydrins are formed when cyanide nucleophiles and carbonyl compounds like aldehydes and ketones react. A strong base, the cyanide ion, catalyzes cyanohydrin formation. The ions are generated from HCN under aqueous conditions. Once the cyanide ions are generated, the first step involves the nucleophilic attack of the cyanide ions on the electrophilic carbonyl carbon. This attack shifts the π electrons from the C=O to the oxygen atom forming the alkoxide ion intermediate. The alkoxide anion...
3.4K
Nitriles to Amines: LiAlH4 Reduction00:55

Nitriles to Amines: LiAlH4 Reduction

3.8K
Nitriles are reduced to amines in the presence of strong reducing agents like lithium aluminum hydride through a typical nucleophilic acyl substitution. The reaction requires two equivalents of the reducing agent. The reducing agent acts as a source of hydride ions.
As shown below, the mechanism involves three steps. Firstly, the hydride ion acting as a nucleophile attacks the nitrile carbon to form an anion. In the second step, a second equivalent of the hydride ion attacks the anion to...
3.8K
ortho–para-Directing Activators: –CH3, –OH, –⁠NH2, –OCH301:11

ortho–para-Directing Activators: –CH3, –OH, –⁠NH2, –OCH3

6.3K
All ortho–para directors, excluding halogens, are activating groups. These groups donate electrons to the ring, making the ring carbons electron-rich. Consequently, the reactivity of the aromatic ring towards electrophilic substitution increases. For instance, the nitration of anisole is about 10,000 times faster than the nitration of benzene. The electron-donating effect of the methoxy group in anisole activates the ortho and para positions on the ring and stabilizes the corresponding...
6.3K
Nucleophilic Addition to the Carbonyl Group: General Mechanism01:18

Nucleophilic Addition to the Carbonyl Group: General Mechanism

5.9K
The carbonyl carbon in an aldehyde or ketone is the site of a nucleophilic attack due to its electron-deficient nature. Depending on the strength of the incoming nucleophile, the reaction occurs via different mechanistic pathways.
A stronger nucleophile can directly attack the electrophilic center, the carbonyl carbon. The HOMO orbital of the nucleophile interacts with the LUMO (π* antibonding) orbital present on the carbonyl carbon. This interaction breaks the π bond and shifts the...
5.9K
Nitriles to Carboxylic Acids: Hydrolysis01:08

Nitriles to Carboxylic Acids: Hydrolysis

4.1K
Nitriles undergo acid-catalyzed hydrolysis or base-catalyzed hydrolysis to form a carboxylic acid. These reactions proceed via an amide intermediate.
4.1K
Radical Substitution: Hydrogenolysis of Alkyl Halides with Tributyltin Hydride01:26

Radical Substitution: Hydrogenolysis of Alkyl Halides with Tributyltin Hydride

1.9K
Radical substitution reactions can be used to remove functional groups from molecules. The hydrogenolysis of alkyl halides is one such reaction, where the weak Sn–H bond in tributyltin hydride reacts with alkyl halides to form alkanes. Here, the reagent Bu3SnH yields tributyltin halide as a byproduct.
The bonds formed in this reaction are stronger than the bonds broken, making it energetically favorable. The reaction follows a radical chain mechanism similar to radical halogenation...
1.9K

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関連する実験動画

Updated: Sep 14, 2025

Hydrolysis of a Ni-Schiff-Base Complex Using Conditions Suitable for Retention of Acid-labile Protecting Groups
06:44

Hydrolysis of a Ni-Schiff-Base Complex Using Conditions Suitable for Retention of Acid-labile Protecting Groups

Published on: April 6, 2017

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構造的に特徴づけられたNi (III) -Hydroxo複合体による基礎度制御C-H結合活性化

Hung-Ruei Pan1, John Wu1, Chun-Ming Tsai1

  • 1Department of Chemistry, National Cheng Kung University, Tainan 701, Taiwan.

Journal of the American Chemical Society
|July 25, 2025
PubMed
まとめ

研究者らは,強いC−H結合を活性化する安定したニッケル−ヒドロキソ複合体を開発した. この発見は,選択的酸化と水素原子移転反応のメカニズムに関する新しい洞察を提供します.

科学分野:

  • 有機金属化学
  • キャタリシス
  • 合成化学

背景:

  • 強いC−H結合の選択的酸化は合成化学における重要な課題である.
  • C-H結合の活性化のためのメカニズムと活性酸化物質は完全に理解されていません.
  • 安定した反応性のある金属-オクソまたは金属-ヒドロキソ複合体の開発は極めて重要です.

研究 の 目的:

  • 単核のNi (III) -ヒドロキソ複合体を分離し,特徴づけること.
  • Ni (III) -ヒドロキソ複合体のC−H結合活性化能力を調査する.
  • 水素原子移転 (HAT) と陽子結合電子移転 (PCET) のメカニズムを解明する.

主な方法:

  • X線結晶学を用いたNi (III) -ヒドロキソ複合体の分離と完全な特徴付け.
  • サイクロヘキサンを含む様々なC-H基板による水素原子移転 (HAT) 反応性研究.
  • 反応速度と基質特性 (pKa,BDE) を相関させるための運動研究.
  • 陽子伝送 (PT) 性質の度合いを決定する半経験的自由エネルギー分析.

主要な成果:

  • 室温に安定する単核ニオール (Ni) -ヒドロキソ複合体[Na 15c 5][Ni PS 3′′) [OH] (2) が成功して合成され,特徴づけられた.

さらに関連する動画

Synthesis of Metal Nanoparticles Supported on Carbon Nanotube with Doped Co and N Atoms and its Catalytic Applications in Hydrogen Production
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Synthesis of Metal Nanoparticles Supported on Carbon Nanotube with Doped Co and N Atoms and its Catalytic Applications in Hydrogen Production

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Protein Film Infrared Electrochemistry Demonstrated for Study of H2 Oxidation by a [NiFe] Hydrogenase
10:01

Protein Film Infrared Electrochemistry Demonstrated for Study of H2 Oxidation by a [NiFe] Hydrogenase

Published on: December 4, 2017

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関連する実験動画

Last Updated: Sep 14, 2025

Hydrolysis of a Ni-Schiff-Base Complex Using Conditions Suitable for Retention of Acid-labile Protecting Groups
06:44

Hydrolysis of a Ni-Schiff-Base Complex Using Conditions Suitable for Retention of Acid-labile Protecting Groups

Published on: April 6, 2017

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Synthesis of Metal Nanoparticles Supported on Carbon Nanotube with Doped Co and N Atoms and its Catalytic Applications in Hydrogen Production
08:40

Synthesis of Metal Nanoparticles Supported on Carbon Nanotube with Doped Co and N Atoms and its Catalytic Applications in Hydrogen Production

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Protein Film Infrared Electrochemistry Demonstrated for Study of H2 Oxidation by a [NiFe] Hydrogenase
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Protein Film Infrared Electrochemistry Demonstrated for Study of H2 Oxidation by a [NiFe] Hydrogenase

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  • 複合体2は強いC−H結合に対する水素原子移転 (HAT) 反応性を示した.
  • 運動研究は,非同期的なPCET経路を示し,主に陽子移転 (PT) によって制御され,ベストフィットx値は0. 18であった.
  • 発生したNi ((II) -aqua種のO−H結合解離自由エネルギーは96.6-100.3 kcalmol−1であると決定された.
  • 結論:

    • Ni (III) -ヒドロキソ複合体2は,強いC−H結合を活性化できる希少な,明確に定義された酸化物質である.
    • 基質の基本性は,PCETの反応性を調節する上で重要な役割を果たします.
    • この発見は,金属-ヒドロキソ種によるC−H結合の酸化に関する貴重なメカニズム的洞察を提供します.