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Thermodynamics, science of the relationship between heat, work, temperature, and energy. In broad terms, thermodynamics deals with the transfer of energy from one place to another and from one form to another. The key concept is that heat is a form of energy corresponding to a definite amount of mechanical work.
Heat was not formally recognized as a form of energy until about 1798, when Count Rumford (Sir Benjamin Thompson), a British military engineer, noticed that limitless amounts of heat could be generated in the boring of cannon barrels and that the amount of heat generated is proportional to the work done in turning a blunt boring tool. Rumford’s observation of the proportionality between heat generated and work done lies at the foundation of thermodynamics. Another pioneer was the French military engineer Sadi Carnot, who introduced the concept of the heat-engine cycle and the principle of reversibility in 1824. Carnot’s work concerned the limitations on the maximum amount of work that can be obtained from a steam engine operating with a high-temperature heat transfer as its driving force. Later that century, these ideas were developed by Rudolf Clausius, a German mathematician and physicist, into the first and second laws of thermodynamics, respectively.

The most important laws of thermodynamics are:

  • The zeroth law of thermodynamics. When two systems are each in thermal equilibrium with a third system, the first two systems are in thermal equilibrium with each other. This property makes it meaningful to use thermometers as the “third system” and to define a temperature scale.
  • The first law of thermodynamics, or the law of conservation of energy. The change in a system’s internal energy is equal to the difference between heat added to the system from its surroundings and work done by the system on its surroundings.
  • The second law of thermodynamics. Heat does not flow spontaneously from a colder region to a hotter region, or, equivalently, heat at a given temperature cannot be converted entirely into work. Consequently, the entropy of a closed system, or heat energy per unit temperature, increases over time toward some maximum value. Thus, all closed systems tend toward an equilibrium state in which entropy is at a maximum and no energy is available to do useful work. This asymmetry between forward and backward processes gives rise to what is known as the “arrow of time.”
  • The third law of thermodynamics. The entropy of a perfect crystal of an element in its most stable form tends to zero as the temperature approaches absolute zero. This allows an absolute scale for entropy to be established that, from a statistical point of view, determines the degree of randomness or disorder in a system.

Although thermodynamics developed rapidly during the 19th century in response to the need to optimize the performance of steam engines, the sweeping generality of the laws of thermodynamics makes them applicable to all physical and biological systems. In particular, the laws of thermodynamics give a complete description of all changes in the energy state of any system and its ability to perform useful work on its surroundings.
This article covers classical thermodynamics, which does not involve the consideration of individual atoms or molecules. Such concerns are the focus of the branch of thermodynamics known as statistical thermodynamics, or statistical mechanics, which expresses macroscopic thermodynamic properties in terms of the behaviour of individual particles and their interactions. It has its roots in the latter part of the 19th century, when atomic and molecular theories of matter began to be generally accepted.

Thermodynamic states:

The application of thermodynamic principles begins by defining a system that is in some sense distinct from its surroundings. For example, the system could be a sample of gas inside a cylinder with a movable piston, an entire steam engine, a marathon runner, the planet Earth, a neutron star, a black hole, or even the entire universe. In general, systems are free to exchange heat, work, and other forms of energy with their surroundings.
A system’s condition at any given time is called its thermodynamic state. For a gas in a cylinder with a movable piston, the state of the system is identified by the temperature, pressure, and volume of the gas. These properties are characteristic parameters that have definite values at each state and are independent of the way in which the system arrived at that state. In other words, any change in value of a property depends only on the initial and final states of the system, not on the path followed by the system from one state to another. Such properties are called state functions. In contrast, the work done as the piston moves and the gas expands and the heat the gas absorbs from its surroundings depend on the detailed way in which the expansion occurs.
The behaviour of a complex thermodynamic system, such as Earth’s atmosphere, can be understood by first applying the principles of states and properties to its component parts—in this case, water, water vapour, and the various gases making up the atmosphere. By isolating samples of material whose states and properties can be controlled and manipulated, properties and their interrelations can be studied as the system changes from state to state.

The document Introduction to Thermodynamics | Basic Physics for IIT JAM is a part of the Physics Course Basic Physics for IIT JAM.
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FAQs on Introduction to Thermodynamics - Basic Physics for IIT JAM

1. What is thermodynamics?
Ans. Thermodynamics is a branch of physics that deals with the study of energy and its transformations, particularly in relation to heat and work. It focuses on understanding how energy flows and is transferred between different systems.
2. What are the laws of thermodynamics?
Ans. The laws of thermodynamics are fundamental principles that govern the behavior of energy in various systems. The four laws are: - The Zeroth Law: If two systems are in thermal equilibrium with a third system, they are in thermal equilibrium with each other. - The First Law: Energy cannot be created or destroyed, only transferred or transformed. - The Second Law: The total entropy of an isolated system always increases in a spontaneous process. - The Third Law: As temperature approaches absolute zero, the entropy of a pure crystalline substance approaches zero.
3. How is thermodynamics applied in everyday life?
Ans. Thermodynamics has various practical applications in everyday life. Some examples include: - Heating and cooling systems: Thermodynamics principles are used in designing efficient HVAC systems for maintaining comfortable indoor temperatures. - Engines and power plants: Thermodynamics is essential for the design and optimization of engines and power plants to convert heat energy into mechanical work. - Refrigeration and air conditioning: Thermodynamics principles are employed in the operation of refrigeration systems and air conditioners. - Cooking: Understanding heat transfer and energy conversion is crucial in cooking processes. - Renewable energy: Thermodynamics is used in the design and analysis of renewable energy systems such as solar panels and wind turbines.
4. What is the difference between heat and temperature?
Ans. Heat and temperature are related but distinct concepts in thermodynamics. Heat refers to the transfer of energy between two objects or systems due to a temperature difference. It is a form of energy transfer. Temperature, on the other hand, is a measure of the average kinetic energy of the particles within a system. It quantifies the hotness or coldness of an object or substance.
5. Can thermodynamics explain why some processes are irreversible?
Ans. Yes, thermodynamics can explain why some processes are irreversible. According to the Second Law of Thermodynamics, the total entropy of an isolated system always increases or remains constant in a reversible process and increases in an irreversible process. Irreversible processes are associated with an increase in the overall disorder or entropy of the system. This increase in entropy is the reason why certain processes, such as the mixing of gases or the dissipation of heat, cannot be reversed without the input of additional energy.
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