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25.4: The Second Law and Entropy
https://phys.libretexts.org/Courses/Merrimack_College/Conservation_Laws_Newton's_Laws_and_Kinematics_version_2.0/25%3A_Thermodynamics/25.04%3A_The_Second_Law_and_Entropy
In the course of each cycle, the engine would take in an amount of heat $Q_h$ from a “hot reservoir,” give off (or “exhaust”) an amount of heat | $Q_c$ | to a “cold reservoir,” and produce an amount...In the course of each cycle, the engine would take in an amount of heat $Q_h$ from a “hot reservoir,” give off (or “exhaust”) an amount of heat | $Q_c$ | to a “cold reservoir,” and produce an amount of work | $W$ |. (I am using absolute value bars here because, from the point of view of the engine, $Q_c$ and $W$ must be negative quantities.) At the end of the cycle, the engine should be back to its initial state, so $\Delta E_{engine} = 0$ .
13.4: The Second Law and Entropy
https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_I_-_Classical_Mechanics_(Gea-Banacloche)/13%3A_Thermodynamics/13.04%3A_The_Second_Law_and_Entropy
In the course of each cycle, the engine would take in an amount of heat $Q_h$ from a “hot reservoir,” give off (or “exhaust”) an amount of heat | $Q_c$ | to a “cold reservoir,” and produce an amount...In the course of each cycle, the engine would take in an amount of heat $Q_h$ from a “hot reservoir,” give off (or “exhaust”) an amount of heat | $Q_c$ | to a “cold reservoir,” and produce an amount of work | $W$ |. (I am using absolute value bars here because, from the point of view of the engine, $Q_c$ and $W$ must be negative quantities.) At the end of the cycle, the engine should be back to its initial state, so $\Delta E_{engine} = 0$ .
1.8: Thermodynamics
https://phys.libretexts.org/Courses/Georgia_State_University/GSU-TM-Introductory_Physics_II_(1112)/zz%3A_Back_Matter/10%3A_13.1%3A_Appendix_J-_Physics_Formulas_(Wevers)/1.08%3A_Thermodynamics
Classical thermodynamics and its statistical basis
8: Thermodynamics
https://phys.libretexts.org/Learning_Objects/A_Physics_Formulary/Physics/08%3A_Thermodynamics
Classical thermodynamics and its statistical basis

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