What is the principle behind electrochemical cells?

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Multiple Choice

What is the principle behind electrochemical cells?

Explanation:
Electrochemical cells are fundamentally designed to convert chemical energy into electrical energy. This transformation occurs through redox reactions, where oxidation and reduction reactions take place in the cell, causing a flow of electrons. In galvanic (or voltaic) cells, spontaneous chemical reactions generate an electric current, illustrating how chemical energy from reactants is harnessed to produce electrical energy. In a typical setup, the cell consists of two electrodes, an anode where oxidation occurs, and a cathode where reduction takes place. The chemical species on the anode loses electrons, while the chemical species on the cathode gains electrons, establishing a flow of electric current through an external circuit, which can be harnessed to do work. This principle underpins many applications, from batteries to fuel cells, highlighting the cell's capacity to transform stored chemical energy into usable electrical energy readily. Understanding this concept is crucial for studying electrochemical cells and their practical implementations.

Electrochemical cells are fundamentally designed to convert chemical energy into electrical energy. This transformation occurs through redox reactions, where oxidation and reduction reactions take place in the cell, causing a flow of electrons. In galvanic (or voltaic) cells, spontaneous chemical reactions generate an electric current, illustrating how chemical energy from reactants is harnessed to produce electrical energy.

In a typical setup, the cell consists of two electrodes, an anode where oxidation occurs, and a cathode where reduction takes place. The chemical species on the anode loses electrons, while the chemical species on the cathode gains electrons, establishing a flow of electric current through an external circuit, which can be harnessed to do work.

This principle underpins many applications, from batteries to fuel cells, highlighting the cell's capacity to transform stored chemical energy into usable electrical energy readily. Understanding this concept is crucial for studying electrochemical cells and their practical implementations.

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