Electricity from spontaneous chemical reactions

Voltaic (or Galvanic) Cells Generating Electricity from Spontaneous Chemical Reactions 865... 

Having covered the chemical behavior of electrolytes, the text is now directed to their electrical behavior. The importance of the chemical and the electrical behaviors of electrolytes in galvanics and electrolytics hardly needs any elaboration. The term galvanics, used here, implies the generation of electrical energy directly from a spontaneous chemical reaction. 

Electrochemical cells produce electrical energy from a spontaneous chemical reaction. In electrolysis, the process is reversed so that electrical energy is used to carry out a nonspontaneous chemical change. A cell arranged to do this is called an electrolytic cell. An electrolytic cell is similar to an electrochemical cell except that an electrolytic cell s circuit includes a power source, for example, a battery. The same electrochemical cell terminology applies to electrolytic cells. Reduction occurs at the cathode and oxidation at the anode. 

So far, we ve focused our attention on voltaic cells, which rely on spontaneous chemical reactions to drive them. In this section, we will look more closely at a different type of cell—one that requires electrical energy from an external source to allow a nonspontaneous reaction to occur. This new type of reaction is known as electrolysis, and it takes place in an electrolytic cell. 

There are two types of electrochemical cells voltaic (galvanic), which produce energy from a chemical reaction, and electrolytic (voltammetric), which require or use up energy. In voltaic cells, a spontaneous chemical reaction produces electricity. These cells are important in potentiometry. In electrolytic cells, electrical energy is used to force a chemical reaction to take place such as in voltammetry. In summary ... 

Electrochemistry is best defined as the study of the interchange of chemical and electrical energy. It is primarily concerned with two processes that involve oxidation-reduction reactions the generation of an electric current from a spontaneous chemical reaction and the opposite process, the use of a current to produce chemical change. 

This reaction is clearly a spontaneous redox reaction, but simply dipping a zinc rod into a copper(II) sulfate solution will not produce useful electric current. However, when we carry out this reaction in the cell shown in Figure 17.5, an electric current is produced. The cell consists of a piece of zinc immersed in a zinc sulfate solution and connected by a wire through a voltmeter to a piece of copper immersed in cop-per(II) sulfate solution. The two solutions are connected by a salt bridge. Such a cell produces an electric current and a potential of about 1.1 volts when both solutions are 1.0 M in concentration. A cell that produces electric current from a spontaneous chemical reaction is called a voltaic cell. A voltaic cell is also known as a galvanic cell. 

A cell that produces electric current from a spontaneous chemical reaction is a voltaic or galvanic cell. 

The generation of electricity through redox reactions is normally carried out in a device called an electrochemical cell. A voltaic (or galvanic) cell, is an electrochonical cell that produces electrical current from a spontaneous chemical reaction. A second type of electrochemical cell, called an electrolytic cell, consumes electrical current to drive a nonspontaneous chemical reaction. We discuss voltaic cells in this section and electrolytic cells in Section 18.8. 

The oxidation of hydrogen to water (Hj -t- i Oj -> HjO) is thermodynamically spontaneous and the energy released as a result of the chemical reaction appears as heat energy, but the decomposition of water into its elements is a non-spontaneous process and can be achieved only by supplying energy from an external source, e.g. a source of e.m.f. that decomposes the water electrolytically. Furthermore, although the heat produced by the spontaneous reaction could be converted into electrical energy, the electrical... 

C14-0117. The notion of thermodynamic coupling of a nonspontaneous process with a spontaneous process is not restricted to chemical reactions. Identify the spontaneous and nonspontaneous portions of the following coupled processes (a) Water behind a dam passes through a turbine and generates electricity, (b) A gasoline engine pumps water from a valley to the top of a hill. 

The electrode processes that are reversible provide values for the equilibrium emfs of cells, which are related to the thermodynamic functions. The condition of reversibility is practically obtained by balancing cell emf against an external emf until only an unappreciable current passes through the cell, in order that the cell reactions proceed very slowly. It may, however, be pointed out that for many of the applications of electrometallurgy, it is clearly necessary to consider more rapid reaction rates. In that situation there is necessarily a departure from the equilibrium condition. Either the cell reactions occur spontaneously to produce electric energy, or an external source of electric energy is used to implement chemical reactions (electrolyses). 

Fuel cells are electrochemical systems that convert the energy of a fuel directly into electric power. The design of a fuel cell is based on the key components an anode, to which the fuel is supplied a cathode, to which the oxidant is supplied and an electrolyte, which permits the flow of ions (but no electrons and reactants) from anode to cathode. The net chemical reaction is exactly the same as if the fuel was burned, but by spatially separating the reactants, the fuel cell intercepts the stream of electrons that spontaneously flow from the reducer (fuel) to the oxidant (oxygen) and diverts it for use in an external circuit. 

Galvanic cell A device in which chemical energy from a spontaneous redox reaction is changed to electrical energy that can be utilized for power. 

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