Mixed

Why do irreversible processes increase entropy?

Why do irreversible processes increase entropy?

Entropy is a non-conserved property, unlike energy. An irreversible process increases the entropy. This is because entropy is a state function, the change in entropy of the system is the same, whether the process is reversible or irreversible. Energy always flows downhill, which causes entropy to increase.

Why is entropy of irreversible process greater than zero?

This heat is absorbed by the system. Thus, in an irreversible process, the entropy change for the combined system and the surroundings i.e. an isolated system is greater than zero i.e. an irreversible process is accompanied by a net increase of entropy.

Can entropy increase in a reversible process?

Entropy is the loss of energy available to do work. Another form of the second law of thermodynamics states that the total entropy of a system either increases or remains constant; it never decreases. Entropy is zero in a reversible process; it increases in an irreversible process.

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Which has more work reversible or irreversible process?

In general, energy released by a reversible process can do the maximum amount of work because less of the energy is lost as heat. A process that is done quickly (irreversibly) tends to generate turbulence and friction resulting in heat loss to the surroundings.

Why are reversible processes more efficient?

Reversible processes do the most work, because they have to push against more external pressure. Since w = -PΔV, a greater value for the external pressure (P) results in a higher (more negative) work.

How does entropy change in reversible process and irreversible process?

The second law of thermodynamics states that in a reversible process, the entropy of the universe is constant, whereas in an irreversible process, such as the transfer of heat from a hot object to a cold object, the entropy of the universe increases.

Why entropy is only for reversible process?

The entropy of various parts of the system may change, but the total change is zero. Furthermore, the system does not affect the entropy of its surroundings, since heat transfer between them does not occur. Thus the reversible process changes neither the total entropy of the system nor the entropy of its surroundings.

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Why does entropy remains constant in reversible process?

Change of entropy along the isothermal line. Mathematically, at every point of a P-V diagram, the system is at equilibrium such that the external pressure equals the internal pressure. Mathematically, there is never any dissimilarity in pressure. So, entropy remains constant in the reversible cycle.