Anodes and Cathodes in Electrochemical Cells
- Anodes and cathodes are essential components of electrochemical cells.
- The first electrochemical battery was invented by Alessandro Volta and called the Voltaic cell.
- The practical battery, known as the Daniell cell, was invented by John Frederic Daniell in 1839.
- Electrochemical cells use two electrodes, anodes and cathodes, to facilitate chemical reactions.
- Anodes are the electrodes through which the conventional current enters the electrochemical cell.
- Cathodes are the electrodes through which the conventional current exits the electrochemical cell.
- The charge of the anode is negative, while the charge of the cathode is positive.
- At the anode, oxidation reactions occur, resulting in the release of electrons.
- At the cathode, reduction reactions occur, where electrons are absorbed.
- The flow of electrons and conventional current determines the direction of electrical flow in the cell.

Primary and Secondary Cells
- Primary cells are designed for single-use and cannot be recharged.
- Alkaline batteries, such as those used in flashlights, are examples of primary cells.
- The electrochemical reactions in primary cells are irreversible.
- Primary cells include zinc–carbon, zinc–chloride, and lithium iron disulfide batteries.
- Recharging primary cells is not recommended due to safety concerns.
- Secondary cells are rechargeable and can be reused multiple times.
- The lead–acid battery, invented by Gaston Planté, was the first rechargeable battery.
- Lead dioxide and solid lead are used as the cathode and anode in lead-acid batteries.
- Other commonly used rechargeable batteries include nickel–cadmium, nickel–metal hydride, and lithium-ion batteries.
- Lithium-ion batteries are widely used in various applications due to their efficiency and performance.

Electrode Efficiency and Properties
- Electrode materials should be conductive to be used as electrodes.
- Conductive materials like metals, semiconductors, graphite, and conductive polymers can be used as electrodes.
- Electrodes often consist of a combination of materials with specific tasks.
- Important properties of electrodes include electrical resistivity, specific heat capacity, electrode potential, and hardness.
- The efficiency of electrochemical cells is determined by properties like self-discharge time, discharge voltage, and cycle performance.
- The values of electrode properties vary depending on the material used.
- Commonly used electrode materials include lithium (Li) and manganese (Mn).
- The cost of the electrode material is also an important factor for technological applications.
- Electrode properties play a significant role in determining the performance of electrochemical cells.

Manufacturing and Structure of Electrodes
- Electrode production involves multiple steps.
- Constituents of the electrode are mixed into a solvent.
- Common components of the mixture include active electrode particles, binder, and conductive agent.
- The mixture is known as an 'electrode slurry'.
- The slurry is coated onto a conductor and dried to the required thickness.
- Internal structure determines the final efficiency of the electrode.
- Clustering of active material and conductive agent affects performance.
- Even distribution of conductive agent optimizes electrode conductivity.
- Adherence of the electrode to current collectors prevents dissolution.
- Density of active material should be balanced with other components.

Electrodes in Lithium-ion Batteries
- Li-ion batteries use electrodes.
- Li-ion batteries are rechargeable and can act as galvanic or electrolytic cells.
- Lithium ions are dissolved in an organic solvent in the electrolyte.
- Li-ion batteries have various applications, such as mobile phones and electric cars.
- Research aims to improve efficiency, safety, and cost of Li-ion battery electrodes.
- Cathodes in Li-ion batteries consist of intercalated lithium compounds.
- Cobalt and manganese are commonly used elements in cathode compounds.
- Cobalt-based compounds have advantages such as high specific heat capacity and voltage.
- Manganese-based compounds have lower cost but tend to dissolve over time.
- Research focuses on finding new materials for cheaper and longer-lasting cathodes.
- Anodes in Li-ion batteries are carbon-based or made of lithium titanate.
- Graphite anodes are widely used due to their price, longevity, and energy density.
- Graphite anodes can experience dendrite growth and pose safety risks.
- Silicon anodes have high capacity but suffer from volumetric expansion issues.
- Metallic lithium is another candidate for anodes, offering high capacity but stability challenges.

Note: Some content may overlap across the groups, but this organization should help consolidate similar concepts.

Merriam-Webster Online Dictionary
electrode (noun)
1.
a conductor used to establish contact with a nonmetallic part of a circuit - electrical
2.
an element in a semiconductor device (as a transistor) that emits or collects or holes or controls their movements - electrons
Electrode (Wikipedia)

An electrode is an electrical conductor used to make contact with a nonmetallic part of a circuit (e.g. a semiconductor, an electrolyte, a vacuum or air). Electrodes are essential parts of batteries that can consist of a variety of materials depending on the type of battery.

Electrodes used in shielded metal arc welding

The electrophore, invented by Johan Wilcke, was an early version of an electrode used to study static electricity.

Electrode (Wiktionary)

English

Etymology

Coined by English scientist Michael Faraday in 1833, first used in his Diary (laboratory notebook) from the Ancient Greek words ἤλεκτρον (ḗlektron, amber) (from which the word electricity is derived) and ὁδός (hodós, way).

Pronunciation

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