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Batteries and Fuel Cells03:12

Batteries and Fuel Cells

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A battery is a galvanic cell that is used as a source of electrical power for specific applications. Modern batteries exist in a multitude of forms to accommodate various applications, from tiny button batteries such as those that power wristwatches to the very large batteries used to supply backup energy to municipal power grids. Some batteries are designed for single-use applications and cannot be recharged (primary cells), while others are based on conveniently reversible cell reactions that...
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Acid Halides to Alcohols: LiAlH4 Reduction01:19

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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...
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Voltaic/Galvanic Cells02:47

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Spontaneous Chemical Reactions
Spontaneous redox reactions occur abundantly in nature. The chemical reaction occurring in a disposable AA battery powering our remote controls is one such example of a spontaneous redox reaction. Another example is the immersion of coiled copper wire into an aqueous silver nitrate solution. The reaction shows a gradual, visually impressive color change from colorless to bright blue and the formation of a grey precipitate on the copper wire. In this experiment,...
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Amides to Amines: LiAlH4 Reduction01:20

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Amide reduction with strong reducing agents like lithium aluminum hydride proceeds through a nucleophilic acyl substitution to form amines. Primary, secondary, and tertiary amides yield primary, secondary, and tertiary amines, respectively.
Amide reduction requires two equivalents of the reducing agent, acting as a source of hydride ions. As shown in the figure, the reaction is initiated with a nucleophilic attack by the hydride ion at the carbonyl carbon to form a tetrahedral intermediate.
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Preparation of Aldehydes and Ketones from Nitriles and Carboxylic Acids01:24

Preparation of Aldehydes and Ketones from Nitriles and Carboxylic Acids

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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]...
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Updated: Aug 29, 2025

Non-aqueous Electrode Processing and Construction of Lithium-ion Coin Cells
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Non-aqueous Electrode Processing and Construction of Lithium-ion Coin Cells

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Recent Progress in Developing a LiOH-Based Reversible Nonaqueous Lithium-Air Battery.

Zongyan Gao1, Israel Temprano2, Jiang Lei1

  • 1Shanghai Key Laboratory of Chemical Assessment and Sustainability, School of Chemical Science and Engineering, Tongji University, No. 1239, Siping Road, Shanghai, 200092, P. R. China.

Advanced Materials (Deerfield Beach, Fla.)
|September 5, 2022
PubMed
Summary

This review explores lithium hydroxide (LiOH) as an alternative to lithium peroxide (Li2O2) for nonaqueous lithium-air batteries (LABs). It details catalytic systems and factors influencing LiOH electrochemistry for improved battery performance.

Keywords:
electrolyte additivesfour-electron OERfour-electron ORRlithium air batterieslithium hydroxidemetal catalysts

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Area of Science:

  • Materials Science
  • Electrochemistry
  • Energy Storage

Background:

  • Nonaqueous lithium-air batteries (LABs) face significant theoretical and technical hurdles.
  • Lithium hydroxide (LiOH) formation/decomposition offers a potential alternative cycling pathway to Li2O2.
  • Developing practical LABs necessitates novel strategies beyond traditional Li2O2 chemistry.

Purpose of the Study:

  • To review progress in LiOH-based nonaqueous LABs.
  • To compare various catalytic systems for LiOH electrochemistry.
  • To elucidate factors influencing the Li2O2 vs. LiOH cycling debate.

Main Methods:

  • Literature review of LiOH-based nonaqueous LABs.
  • Comparative analysis of soluble and solid-state catalytic systems.
  • Discussion of reaction mechanisms and influencing factors.

Main Results:

  • Detailed comparison of catalytic systems activating LiOH electrochemistry.
  • Updated understanding of oxygen reduction and evolution reactions in nonaqueous media.
  • Identification of key factors controlling the switch between Li2O2 and LiOH chemistries.

Conclusions:

  • The LiOH pathway presents a promising alternative for nonaqueous LABs.
  • Reaction intermediates, redox mediators, additives, interfaces, parasitic reactions, and CO2 significantly impact LiOH electrochemistry.
  • Further investigation is warranted to fully understand and optimize LiOH-based LABs.