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Acid Halides to Alcohols: LiAlH4 Reduction01:19

Acid Halides to Alcohols: LiAlH4 Reduction

2.8K
Acid halides are reduced to alcohols in the presence of a strong reducing agent like lithium aluminum hydride.
The mechanism proceeds in three steps. First, the nucleophilic hydride ion attacks the carbonyl carbon of the acid halide to form a tetrahedral intermediate. Next, the carbonyl group is re-formed, and the halide ion departs as a leaving group, generating an aldehyde. A second nucleophilic attack by the hydride yields an alkoxide ion, which, upon protonation, gives a primary alcohol as...
2.8K
Preparation of Aldehydes and Ketones from Nitriles and Carboxylic Acids01:24

Preparation of Aldehydes and Ketones from Nitriles and Carboxylic Acids

3.5K
Although it is possible to reduce a carboxylic acid to an aldehyde, strong reducing agents, like lithium aluminum hydride (LAH), prohibit a controlled reduction, instead causing the generated aldehyde to instantly over-reduce to a primary alcohol.
Reducing carboxylic acid derivatives like acyl chlorides (RCOCl), esters (RCO2R′), and nitriles (RCN) using milder aluminum hydride agents like lithium tri-tert-butoxyaluminum hydride [LiAlH(O-t-Bu)3] and diisobutylaluminum hydride [DIBAL-H]...
3.5K
Hydroboration-Oxidation of Alkenes03:08

Hydroboration-Oxidation of Alkenes

8.2K
In addition to the oxymercuration–demercuration method, which converts the alkenes to alcohols with Markovnikov orientation, a complementary hydroboration-oxidation method yields the anti-Markovnikov product. The hydroboration reaction, discovered in 1959 by H.C. Brown, involves the addition of a B–H bond of borane to an alkene giving an organoborane intermediate. The oxidation of this intermediate with basic hydrogen peroxide forms an alcohol.
8.2K
Carboxylic Acids to Primary Alcohols: Hydride Reduction01:17

Carboxylic Acids to Primary Alcohols: Hydride Reduction

2.9K
Carboxylic acids, upon reaction with strong reducing agents such as lithium aluminum hydride followed by hydrolysis, undergo reduction to form primary alcohols.
2.9K
Esters to Alcohols: Hydride Reductions01:17

Esters to Alcohols: Hydride Reductions

3.5K
Esters are reduced to primary alcohols when treated with a strong reducing agent like lithium aluminum hydride. The reaction requires two equivalents of the reducing agent and proceeds via an aldehyde intermediate.
Lithium aluminum hydride is a source of hydride ions and functions as a nucleophile. The mechanism proceeds in three steps. Firstly, the nucleophilic hydride ion attacks the carbonyl carbon of the ester to form a tetrahedral intermediate. Subsequently, the carbonyl group re-forms,...
3.5K
Radical Substitution: Hydrogenolysis of Alkyl Halides with Tributyltin Hydride01:26

Radical Substitution: Hydrogenolysis of Alkyl Halides with Tributyltin Hydride

1.8K
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...
1.8K

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Updated: Jul 4, 2025

A Simple, Low-cost, and Robust System to Measure the Volume of Hydrogen Evolved by Chemical Reactions with Aqueous Solutions
06:32

A Simple, Low-cost, and Robust System to Measure the Volume of Hydrogen Evolved by Chemical Reactions with Aqueous Solutions

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Producing Alkali Metal Hydrides from Hydroxides.

Ainee Ibrahim1, Mark Paskevicius1, Terry D Humphries1

  • 1Physics and Astronomy, Institute for Energy Transition, Curtin University, GPO Box U1987, Perth, WA 6845, Australia.

Inorganic Chemistry
|January 29, 2024
PubMed
Summary
This summary is machine-generated.

Researchers developed a cost-effective method to produce alkali metal hydrides from hydroxides. This novel process simplifies purification and shows potential for sodium borohydride applications.

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Area of Science:

  • Inorganic Chemistry
  • Materials Science
  • Chemical Engineering

Background:

  • Alkali metal hydrides are crucial chemical intermediates.
  • Existing production methods can be complex and costly.
  • There is a need for efficient and scalable hydride synthesis.

Purpose of the Study:

  • To present a novel, cost-effective method for producing alkali metal hydrides (NaH, KH, RbH, CsH) from their corresponding metal hydroxides.
  • To investigate various metallic reducing agents for sodium hydride (NaH) production from sodium hydroxide (NaOH).
  • To explore the potential of this NaH production method for sodium borohydride (NaBH4) applications and hydrogen export.

Main Methods:

  • Reactions conducted in an autoclave reactor under controlled conditions (250 °C, 14 bar H2 pressure) using paraffin oil.
  • Investigated metallic reducing agents including Mg, Al, Si, CaH2, Cr, Mn, and Sr for NaH synthesis.
  • Implemented a two-step process involving metal formation followed by hydrogenation to simplify purification.

Main Results:

  • Successfully produced various alkali metal hydrides from their respective hydroxides.
  • Identified effective metallic reducing agents for NaH production.
  • Demonstrated that a two-step process enhances separation and purification of metal hydrides.

Conclusions:

  • The presented method offers a viable, cost-effective alternative for alkali metal hydride production.
  • The process is adaptable for producing sodium hydride, with implications for sodium borohydride synthesis and hydrogen storage.
  • This research contributes to advancing efficient chemical synthesis and hydrogen economy technologies.