วันอาทิตย์ที่ 4 พฤษภาคม พ.ศ. 2557

Second Law of Thermodynamics

By charnwit kheanpanya
   
        Second law of thermodynamics
                   "It is impossible for a process to have as its sole result the transfer of heat from a cooler body to a hotter one."
     
           Second law of thermodynamics is perhaps the most popular outside of the real of physics, because it is closely related to the concept of entropy, or the disorder created during a thermodynamic process. Reformulated as a statement regarding entropy, the second law reads:
        
"In any closed system, the entropy of the system will either remain constant or increase."
In other words, each time a system goes through a thermodynamic process, the system can never completely return to precisely the same state it was in before. This is one definition used for the arrow of time, since entropy of the universe will always increase over time according to the second law of thermodynamics.

           The change in entropy (ΔS) was originally defined for a thermodynamically reversible process as

        Which is found from the uniform  temperature (T ) of a closed system dividing an incremental reversible transfer of heat into that system (dQ). The above definition is sometimes called the macroscopic definition of entropy because it can be used without regard to any microscopic picture of the contents of a system. In thermodynamics, entropy has been found to be more generally useful and it has several other formulations. Entropy was discovered when it was noticed to be a quantity that behaves as a function of state, as a consequence of the second law of thermodynamics. Entropy is an extensive property, but the entropy of a pure substance is usually given as an intensive property — either specific entropy (entropy per unit mass) or molar entropy (entropy per mole).             
          The absolute entropy (S  rather than ΔS) was defined later, using either statistical mechanics or the third law of thermodynamics.
           Entropy has the dimension of energy divided by temperature, which has a unit of joules per kelvin (J/K) in the International System of Units.
           This summary  covers the relevant relations concerning entropy generation , entropy evaluation and isentropic processes.

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