Isentropic process: Difference between revisions
imported>Paul Wormer (New page: {{subpage}} In thermodynamics, an '''isentropic process''' is a process of constant entropy. The entropy of a thermodynamic system can change by two causes: (i) by transferral of [...) |
imported>Mark Widmer m ("Entropy" link now links to "Entropy_(thermodynamics)," instead of "Entropy" disambiguation page.) |
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In [[thermodynamics]], an '''isentropic process''' is a process of constant [[entropy]]. The entropy of a thermodynamic system can change by two causes: (i) by transferral of [[heat]] in or out the system, and (ii) by a spontaneous (natural) process inside the system that, by the [[second law of thermodynamics]], is accompanied by an entropy ''increase''. | In [[thermodynamics]], an '''isentropic process''' is a process of constant [[Entropy_(thermodynamics)|entropy]]. The entropy of a thermodynamic system can change by two causes: (i) by transferral of [[heat]] in or out the system, and (ii) by a spontaneous (natural) process inside the system that, by the [[second law of thermodynamics]], is accompanied by an entropy ''increase''. | ||
If a system has [[adiabatic]] walls, heat cannot enter or leave the system, and the first cause of possible change of entropy does not occur. A process, taking place without heat entering or exiting, is called an ''adiabatic'' process. If a process is quasi-static (also known as reversible), there is no spontaneous increase of entropy, hence, in short, an isentropic process is quasi-static ''and'' adiabatic. | If a system has [[adiabatic]] walls, heat cannot enter or leave the system, and the first cause of possible change of entropy does not occur. A process, taking place without heat entering or exiting, is called an ''adiabatic'' process. If a process is quasi-static (also known as reversible), there is no spontaneous increase of entropy, hence, in short, an isentropic process is quasi-static ''and'' adiabatic. | ||
In actual practice, quasi-static (reversible) processes do not occur; the concept of reversibility is an idealization, an unachievable limit, but useful for theoretical considerations. | In actual practice, quasi-static (reversible) processes do not occur; the concept of reversibility is an idealization, an unachievable limit, but useful for theoretical considerations. |
Latest revision as of 16:29, 16 January 2022
In thermodynamics, an isentropic process is a process of constant entropy. The entropy of a thermodynamic system can change by two causes: (i) by transferral of heat in or out the system, and (ii) by a spontaneous (natural) process inside the system that, by the second law of thermodynamics, is accompanied by an entropy increase.
If a system has adiabatic walls, heat cannot enter or leave the system, and the first cause of possible change of entropy does not occur. A process, taking place without heat entering or exiting, is called an adiabatic process. If a process is quasi-static (also known as reversible), there is no spontaneous increase of entropy, hence, in short, an isentropic process is quasi-static and adiabatic.
In actual practice, quasi-static (reversible) processes do not occur; the concept of reversibility is an idealization, an unachievable limit, but useful for theoretical considerations.