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Bonding in Metals02:32

Bonding in Metals

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Metallic bonds are formed between two metal atoms. A simplified model to describe metallic bonding has been developed by Paul Drüde called the “Electron Sea Model”. 
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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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Metal-Ligand Bonds02:51

Metal-Ligand Bonds

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The hemoglobin in the blood, the chlorophyll in green plants, vitamin B-12, and the catalyst used in the manufacture of polyethylene all contain coordination compounds. Ions of the metals, especially the transition metals, are likely to form complexes.
In these complexes, transition metals form coordinate covalent bonds, a kind of Lewis acid-base interaction in which both of the electrons in the bond are contributed by a donor (Lewis base) to an electron acceptor (Lewis acid). The Lewis acid in...
20.5K
Complexation Equilibria: The Chelate Effect01:19

Complexation Equilibria: The Chelate Effect

425
In complexation reactions, metal atoms or cations interact with ligands to form donor-acceptor adducts called metal complexes. Ligands that bind through one donor site are monodentate, ligands with two donor sites are bidentate, and those with more than two donor sites are polydentate ligands. For example, ethylene diamine is a bidentate ligand that binds through two nitrogen donor atoms, forming a five-membered ring. EDTA is a polydentate ligand that binds through four oxygen and two nitrogen...
425
Extraction: Advanced Methods00:56

Extraction: Advanced Methods

403
Metal ions can be separated from one another by complexation with organic ligands–the chelating agent– to form uncharged chelates. Here, the chelating agent must contain hydrophobic groups and behave as a weak acid, losing a proton to bind with the metal. Since most organic ligands used in this process are insoluble or undergo oxidation in the aqueous phase, the chelating agent is initially added to the organic phase and extracted into the aqueous phase. The metal-ligand complex is...
403
Complexation Equilibria: Factors Influencing Stability of Complexes01:09

Complexation Equilibria: Factors Influencing Stability of Complexes

319
In complexation reactions, metal cations are the electron pair acceptors, and the ligands are the electron pair donors. The stability of the metal complexes depends primarily on the complexing ability of the central metal ion and the nature of the ligands. Generally, the complexing ability of the metal ion depends on the size and charge of the ion. As the metal ion size increases, the stability of the metal complexes decreases, provided that the valency of the metal ion and the ligands remain...
319

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Related Experiment Video

Updated: May 8, 2026

Construction and Testing of Coin Cells of Lithium Ion Batteries
07:23

Construction and Testing of Coin Cells of Lithium Ion Batteries

Published on: August 2, 2012

Enabling high-performance multivalent metal-ion batteries: current advances and future prospects.

Asif Mahmood1, Zhe Bai2, Tan Wang2

  • 1Centre for Clean Energy Technology, School of Mathematical and Physical Sciences, Faculty of Science, University of Technology Sydney, City Campus, Broadway, NSW 2007, Australia. asif.mahmood@uts.edu.au.

Chemical Society Reviews
|January 31, 2025
PubMed
Summary
This summary is machine-generated.

Multivalent metal-ion batteries (MVIBs) offer a promising alternative to lithium-ion batteries due to abundant materials and higher safety. This review details advancements in MVIBs, addressing challenges for next-generation energy storage.

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Characterization of Electrode Materials for Lithium Ion and Sodium Ion Batteries Using Synchrotron Radiation Techniques

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Synthesis of Ionic Liquid Based Electrolytes, Assembly of Li-ion Batteries, and Measurements of Performance at High Temperature
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Last Updated: May 8, 2026

Construction and Testing of Coin Cells of Lithium Ion Batteries
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Construction and Testing of Coin Cells of Lithium Ion Batteries

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Characterization of Electrode Materials for Lithium Ion and Sodium Ion Batteries Using Synchrotron Radiation Techniques
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Characterization of Electrode Materials for Lithium Ion and Sodium Ion Batteries Using Synchrotron Radiation Techniques

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Synthesis of Ionic Liquid Based Electrolytes, Assembly of Li-ion Batteries, and Measurements of Performance at High Temperature
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Synthesis of Ionic Liquid Based Electrolytes, Assembly of Li-ion Batteries, and Measurements of Performance at High Temperature

Published on: December 20, 2016

Area of Science:

  • Electrochemistry
  • Materials Science
  • Energy Storage

Background:

  • Lithium-ion batteries dominate the market but face challenges due to lithium's scarcity and cost.
  • Multivalent metal-ion batteries (MVIBs) are emerging as a sustainable alternative, utilizing abundant metals like Zn, Mg, Ca, and Al.
  • MVIBs offer potential advantages in cost, safety, and volumetric capacity compared to Li-ion batteries.

Purpose of the Study:

  • To comprehensively review recent advancements in electrode, electrolyte, and separator materials for MVIBs.
  • To highlight the potential of MVIBs to surpass Li-ion batteries in terms of cost, energy density, and safety.
  • To provide an overview of challenges and future directions in MVIB technology.

Main Methods:

  • Literature review of recent progress in MVIB chemistries and charge storage mechanisms.
  • Analysis of challenges including ion kinetics, electrode stability, and interfacial resistance.
  • Exploration of proposed methodologies: anode/cathode design, electrolyte modifications, solid-state electrolytes, and separator advancements.

Main Results:

  • MVIBs show potential for higher volumetric capacities and improved safety profiles.
  • Significant progress has been made in designing electrode and electrolyte materials tailored for multivalent ions.
  • Advanced characterization tools and artificial intelligence are increasingly used to understand MVIB mechanisms.

Conclusions:

  • MVIBs represent a significant advancement in next-generation energy storage solutions.
  • Material innovation and sustainable practices are crucial for realizing the full potential of MVIB technology.
  • Further research into overcoming challenges in kinetics and stability will accelerate MVIB commercialization.