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An isothermal process studied in this chapter is quasi-statically performed, since to be isothermal throughout the change of volume, you must be able to state the temperature of the system at each step, which is possible only if the system is in thermal equilibrium continuously. The system must go out of equilibrium for the state to change, but for quasi-static processes, we imagine that the process is conducted in infinitesimal steps such that these departures from equilibrium can be made as brief and as small as we like.

Other quasi-static processes of interest for gases are isobaric and isochoric processes. An isobaric process    is a process where the pressure of the system does not change, whereas an isochoric process    is a process where the volume of the system does not change.

Adiabatic processes

In an adiabatic process    , the system is insulated from its environment so that although the state of the system changes, no heat is allowed to enter or leave the system, as seen in [link] . An adiabatic process can be conducted either quasi-statically or non-quasi-statically. When a system expands adiabatically, it must do work against the outside world, and therefore its energy goes down, which is reflected in the lowering of the temperature of the system. An adiabatic expansion leads to a lowering of temperature, and an adiabatic compression leads to an increase of temperature. We discuss adiabatic expansion again in Adiabatic Processes for an ideal Gas .

The figure is an illustration of a container closed by a piston. The container has double walls and bottom, with the gap filled with insulation. The region inside the container, below the piston, is labeled as the system. An upward arrow indicates that the piston moves up.
An insulated piston with a hot, compressed gas is released. The piston moves up, the volume expands, and the pressure and temperature decrease. The internal energy goes into work. If the expansion occurs within a time frame in which negligible heat can enter the system, then the process is called adiabatic. Ideally, during an adiabatic process no heat enters or exits the system.

Cyclic processes

We say that a system goes through a cyclic process    if the state of the system at the end is same as the state at the beginning. Therefore, state properties such as temperature, pressure, volume, and internal energy of the system do not change over a complete cycle:

Δ E int = 0 .

When the first law of thermodynamics is applied to a cyclic process, we obtain a simple relation between heat into the system and the work done by the system over the cycle:

Q = W ( cyclic process ) .

Thermodynamic processes are also distinguished by whether or not they are reversible. A reversible process    is one that can be made to retrace its path by differential changes in the environment. Such a process must therefore also be quasi-static. Note, however, that a quasi-static process is not necessarily reversible, since there may be dissipative forces involved. For example, if friction occurred between the piston and the walls of the cylinder containing the gas, the energy lost to friction would prevent us from reproducing the original states of the system.

We considered several thermodynamic processes:

  1. An isothermal process, during which the system’s temperature remains constant
  2. An adiabatic process, during which no heat is transferred to or from the system
  3. An isobaric process, during which the system’s pressure does not change
  4. An isochoric process, during which the system’s volume does not change
Practice Key Terms 7

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Source:  OpenStax, University physics volume 2. OpenStax CNX. Oct 06, 2016 Download for free at http://cnx.org/content/col12074/1.3
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