Electrochemical cells cell spontaneity

An electrochemical cell which spontaneously produces current (or energy) when the electrodes are connected externally by a conducting wire. 

A battery is defined as a device for converting chemical energy into electrical energy. A battery is therefore an electrochemical cell that spontaneously produces a current when the two electrodes are connected externally by a conductor. The conductor will be the sea in the example of the eel above, or will more typically be a conductive... 

Why is it that half-reactions in electrochemical cells proceed spontaneously in one direction and furnish current ... 

Galvanic Cdl An electrochemical cell with spontaneous reactions. 

An electrochemical cell is a device by means of which the enthalpy (or heat content) of a spontaneous chemical reaction is converted into electrical energy conversely, an electrolytic cell is a device in which electrical energy is used to bring about a chemical change with a consequent increase in the enthalpy of the system. Both types of cells are characterised by the fact that during their operation charge transfer takes place at one electrode in a direction that leads to the oxidation of either the electrode or of a species in solution, whilst the converse process of reduction occurs at the other electrode. 

There are two principal methods of applying cathodic protection, viz. the impressed current technique and the use of sacrificial anodes. The former includes the structure as part of a driven electrochemical cell and the latter includes the structure as part of a spontaneous galvanic cell. 

To a chemist, electrochemical cells are of interest primarily for the information they yield CENGAGENOW concerning the spontaneity of redox reactions, the strengths of oxidizing and reducing Click Chemistry Interactive for a self-study... 

In electrochemical cells we often find convective transport of reaction components toward (or away from) the electrode surface. In this case the balance equation describing the supply and escape of the components should be written in the general form (1.38). However, this equation needs further explanation. At any current density during current flow, the migration and diffusion fluxes (or field strength and concentration gradients) will spontaneously settle at values such that condition (4.14) is satisfied. The convective flux, on the other hand, depends on the arbitrary values selected for the flow velocity v and for the component concentrations (i.e., is determined by factors independent of the values selected for the current density). Hence, in the balance equation (1.38), it is not the total convective flux that should appear, only the part that corresponds to the true consumption of reactants from the flux or true product release into the flux. This fraction is defined as tfie difference between the fluxes away from and to the electrode ... 

Many elements of the p-block of the periodic table spontaneously adsorb on the surface of a platinum electrode when this is immersed in a solution containing a soluble salt of the element, without an external supply of electricity [Clavilier et al., 1988, 1989a, b, 1990a, b Evans and Attard, 1993 Feliu et al., 1988, 1991, 1993a, b Gomez et al., 1992 Sung et al., 1997, 1998]. The electrode can then be rinsed and transferred to an electrochemical cell that does not contain the corresponding ion of the deposited element, which remains on the surface, irreversibly adsorbed. 

Having introduced matters pertaining to the electrochemical series earlier, it is only relevant that an appraisal is given on some of its applications. The coverage hereunder describes different examples which include aspects of spontaneity of a galvanic cell reaction, feasibility of different species for reaction, criterion of choice of electrodes to form galvanic cells, sacrificial protection, cementation, concentration and tempera lure effects on emf of electrochemical cells, clues on chemical reaction, caution notes on the use of electrochemical series, and finally determination of equilibrium constants and solubility products. 

The cathode is defined as the electrode at which reduction occurs, i.e., where electrons are consumed, regardless of whether the electrochemical cell is an electrolytic or voltaic cell. In both electrolytic and voltaic cells, the electrons flow through the wire from the anode, where electrons are produced, to the cathode, where electrons are consumed. In an electrolytic cell, the dc source forces the electrons to travel nonspontaneously through the wire. Thus, the electrons flow from the positive electrode (the anode) to the negative electrode (the cathode). However, in a voltaic cell, the electrons flow spontaneously, away from the negative electrode (the anode) and toward the positive electrode (the cathode). 

Potentiometry deals with the electromotive force (EMF) generated in a galvanic cell where a spontaneous chemical reaction is taking place. In practice, potentiometry employs the EMF response of a galvanostatic cell that is based on the measurement of an electrochemical cell potential under zero-current conditions to determine the concentration of analytes in measuring samples. Because an electrode potential generated on the metal electrode surface,... 

The electrochemical cell with zinc and copper electrodes had an overall potential difference that was positive (+1.10 volts), so the spontaneous chemical reactions produced an electric current. Such a cell is called a voltaic cell. In contrast, electrolytic cells use an externally generated electrical current to produce a chemical reaction that would not otherwise take place. 

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. 

In an electrolytic process, redox reactions that occur spontaneously in electrochemical cells can be reversed. One of the most common electrolytic procedures demonstrating this is when a battery is... 

A positive standard cell potential tells you that the cathode is at a higher potential than the anode, and the reaction is therefore spontaneous. What do you do with a cell that has a negative " gii Electrochemical cells that rely on such nonspontaneous reactions cire called electrolytic cells. The redox reactions in electroljdic cells rely on a process called electrolysis. These reactions require that a current be passed through the solution, forcing it to split into components that then fuel the redox reaction. Such cells are created by applying a current source, such as a battery, to electrodes placed in a solution of molten salt, or salt heated until it melts. This splits the ions that make up the salt. 

Thus, the tables of standard electrode potentials predict those processes that tend to occur spontaneously if any pair of listed interfacial systems are built into an electrochemical cell that with the lower (algebraically, i.e., more negative) standard potential will spontaneously undergo deelectronation (oxidation), while that with the higher potential (i.e., more positive) will spontaneously undergo electronation (reduction). 

Fig. 2.1 Basic electrochemical cell. Interconnection of the two electrodes through the external load resistor allows the spontaneous cell reaction io proceed...

Is an acidified aqueous permanganate solution a more powerful oxidizing agent than an acidified aqueous dichromate solution under standard conditions Design an electrochemical cell that could be used to answer the question. Write the chemical equation for the spontaneous reaction between the two reagents and determine the standard cell potential. 

Electrochemical cells may be one of two types. Should a current spontaneously flow on connecting the electrodes via a conductor, the cell is a galvanic cell. An electrolytic cell is one in which reactions occur when an external voltage greater than the reversible potential of the cell is applied. Simple examples involving copper are given in Figure 1. It is the electrolytic cell which is of interest in the electrodeposition of metals. 

Batteries are everywhere in modern societies. They provide the electric current to start our automobiles and to power a host of products such as pocket calculators, digital watches, heart pacemakers, radios, and tape recorders. A battery is an electrochemical cell, a device for interconverting chemical and electrical energy. A battery takes the energy released by a spontaneous chemical reaction and uses it to produce electricity. 

Electrochemical cells are of two basic types galvanic cells (also called voltaic cells) and electrolytic cells. The names "galvanic" and "voltaic" honor the Italian scientists Luigi Galvani (1737-1798) and Alessandro Volta (1745-1827), who conducted pioneering work in the field of electrochemistry. In a galvanic cell, a spontaneous... 

Thus far, we ve been concerned only with galvanic cells—electrochemical cells in which a spontaneous redox reaction produces an electric current. A second important kind of electrochemical cell is the electrolytic cell, in which an electric current is used to drive a nonspontaneous reaction. Thus, the processes occurring in galvanic and electrolytic cells are the reverse of each other A galvanic cell converts... 

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