The second law of thermodynamics.
![the second law of thermodynamics. the second law of thermodynamics.](https://i.ytimg.com/vi/DWiCaDPM7Hk/maxresdefault.jpg)
If an isolated system containing distinct subsystems is held initially in internal thermodynamic equilibrium by internal partitioning impermeable walls between the subsystems, and then some operation makes the walls more permeable, then the system spontaneously evolves to reach a final new internal thermodynamic equilibrium, and its total entropy, S, increases.
![the second law of thermodynamics. the second law of thermodynamics.](https://2.bp.blogspot.com/-mxc5CBVhUmc/V_skBpoFkzI/AAAAAAAACng/uKBIvU565WIOtfpsDkSkgk-O4nu0xowNACLcB/s1600/2nd-law-of-thermodynamics.jpg)
Such phenomena are accounted for in terms of entropy change. For example, when a path for conduction and radiation is made available, heat always flows spontaneously from a hotter to a colder body. It asserts that a natural process runs only in one sense, and is not reversible. The second law is concerned with the direction of natural processes. It can be linked to the law of conservation of energy.
![the second law of thermodynamics. the second law of thermodynamics.](https://image1.slideserve.com/1596874/second-law-of-thermodynamics1-l.jpg)
The first law of thermodynamics provides the definition of the internal energy of a thermodynamic system, and expresses its change for a closed system in terms of work and heat. Heat flowing from hot water to cold water 7.2 Derivation for systems described by the canonical ensemble.7.1 Derivation of the entropy change for reversible processes.7 Derivation from statistical mechanics.4.1 The second law in chemical thermodynamics.3.1 Perpetual motion of the second kind.2.10 Statement for a system that has a known expression of its internal energy as a function of its extensive state variables.2.6 Relation between Kelvin's statement and Planck's proposition.2.4 Equivalence of the Clausius and the Kelvin statements.The second law of thermodynamics can also be used to define the concept of thermodynamic temperature, but this is usually delegated to the zeroth law of thermodynamics. The first rigorous definition of the second law based on the concept of entropy came from German scientist Rudolph Clausius in the 1850s and included his statement that heat can never pass from a colder to a warmer body without some other change, connected therewith, occurring at the same time. Its first formulation, which preceded the proper definition of entropy and was based on caloric theory, is Carnot's theorem, credited to the French scientist Sadi Carnot, who in 1824 showed that the efficiency of conversion of heat to work in a heat engine has an upper limit. The second law has been expressed in many ways. Statistical mechanics provides a microscopic explanation of the law in terms of probability distributions of the states of large assemblies of atoms or molecules. Historically, the second law was an empirical finding that was accepted as an axiom of thermodynamic theory. An increase in the combined entropy of system and surroundings accounts for the irreversibility of natural processes, often referred to in the concept of the arrow of time. The second law may be formulated by the observation that the entropy of isolated systems left to spontaneous evolution cannot decrease, as they always arrive at a state of thermodynamic equilibrium where the entropy is highest at the given internal energy. It can be used to predict whether processes are forbidden despite obeying the requirement of conservation of energy as expressed in the first law of thermodynamics and provides necessary criteria for spontaneous processes.
![the second law of thermodynamics. the second law of thermodynamics.](https://image1.slideserve.com/1531634/the-second-law-of-thermodynamics-1-l.jpg)
The second law of thermodynamics establishes the concept of entropy as a physical property of a thermodynamic system.