thermodynamic temperature

(noun)

Temperature defined in terms of the laws of thermodynamics rather than the properties of a real material: expressed in kelvins.

Related Terms

Examples of thermodynamic temperature in the following topics:

  • A Review of the Zeroth Law

    • Zeroth law justifies the use of thermodynamic temperature, defined as the shared temperature of three designated systems at equilibrium.
    • This conclusion may seem obvious, because all three have the same temperature, but zeroth law is basic to thermodynamics.
    • Zeroth law justifies the use of thermodynamic temperature : the common "label" that the three systems in the definition above share is defined as the temperature of the systems.
    • Thermometers actually take their own temperature, not the temperature of the object they are measuring.
    • Discuss how the Zeroth Law of Thermodynamics justifies the use of thermodynamic temperature

  • Absolute Temperature

    • Absolute temperature is the most commoly used thermodyanmic temperature unit and is the standard unit of temperature.
    • Thermodynamic temperature is the absolute measure of temperature.
    • It is one of the principal parameters of thermodynamics and kinetic theory of gases.
    • Thermodynamic temperature is an "absolute" scale because it is the measure of the fundamental property underlying temperature: its null or zero point ("absolute zero") is the temperature at which the particle constituents of matter have minimal motion and cannot become any colder.
    • By using the absolute temperature scale (Kelvin system), which is the most commonly used thermodynamic temperature, we have shown that the average translational kinetic energy (KE) of a particle in a gas has a simple relationship to the temperature:

  • Kelvin Scale

    • The kelvin is a unit of measurement for temperature; the null point of the Kelvin scale is absolute zero, the lowest possible temperature.
    • The Kelvin scale is an absolute, thermodynamic temperature scale using absolute zero as its null point.
    • In the classical description of thermodynamics, absolute zero is the temperature at which all thermal motion ceases.
    • The kelvin is defined as the fraction 1/273.16 of the thermodynamic temperature of the triple point of water (exactly 0.01°C, or 32.018°F).
    • A brief introduction to temperature and temperature scales for students studying thermal physics or thermodynamics.

  • Absolute Zero

    • Absolute zero is the coldest possible temperature; formally, it is the temperature at which entropy reaches its minimum value.
    • Absolute zerois the coldest possible temperature.
    • However, in the interpretation of classical thermodynamics, kinetic energy can be zero, and the thermal energy of matter vanishes.
    • The zero point of a thermodynamic temperature scale, such as the Kelvin scale, is set at absolute zero.
    • A brief introduction to temperature and temperature scales for students studying thermal physics or thermodynamics.

  • The Zeroth Law of Thermodynamics

    • The Zeroth Law of Thermodynamics states that systems in thermal equilibrium are at the same temperature.
    • There are a few ways to state the Zeroth Law of Thermodynamics, but the simplest is as follows: systems that are in thermal equilibrium exist at the same temperature.
    • What the Zeroth Law of Thermodynamics means is that temperature is something worth measuring, because it indicates whether heat will move between objects.
    • Temperature is not mentioned explicitly, but it's implied that temperature exists.
    • The systems A, B, and C are at the same temperature.

  • The Third Law of Thermodynamics and Absolute Energy

    • The third law of thermodynamics states that the entropy of a system approaches a constant value as the temperature approaches absolute zero.
    • The third law of thermodynamics states that the entropy of a system approaches a constant value as the temperature approaches zero.
    • Specifically, the entropy of a pure crystalline substance at absolute zero temperature is zero.
    • At zero temperature the system must be in a state with the minimum thermal energy.
    • The entropy (S) of a substance (compound or element) as a function of temperature (T).

  • The Three Laws of Thermodynamics

    • The laws of thermodynamics define fundamental physical quantities (temperature, energy, and entropy) that characterize thermodynamic systems.
    • In order to avoid confusion, scientists discuss thermodynamic values in reference to a system and its surroundings.
    • The second law of thermodynamics says that the entropy of any isolated system always increases.
    • The third law of thermodynamics states that the entropy of a system approaches a constant value as the temperature approaches absolute zero.
    • Specifically, the entropy of a pure crystalline substance (perfect order) at absolute zero temperature is zero.

  • The Second Law

    • The second law of thermodynamics states that heat transfer occurs spontaneously only from higher to lower temperature bodies.
    • The second law of thermodynamics deals with the direction taken by spontaneous processes.
    • For example, heat involves the transfer of energy from higher to lower temperature.
    • The law that forbids these processes is called the second law of thermodynamics .
    • The Second Law of Thermodynamics(first expression): Heat transfer occurs spontaneously from higher- to lower-temperature bodies but never spontaneously in the reverse direction.

  • Changes in Energy

    • In classical thermodynamics the entropy is interpreted as a state function of a thermodynamic system.
    • The entropy of a system is defined only if it is in thermodynamic equilibrium.
    • In a thermodynamic system, pressure, density, and temperature tend to become uniform over time because this equilibrium state has a higher probability (more possible combinations of microstates) than any other.
    • Over time, the temperature of the glass and its contents and the temperature of the room become equal.
    • The second law of thermodynamics shows that in an isolated system internal portions at different temperatures will tend to adjust to a single uniform temperature and thus produce equilibrium.

  • Thermodynamics

    • A blackbody is of course characterized by a single temperature, $T$.
    • There are three characteristic temperatures in common usage: brightness temperature, effective temperature and the colour temperature.
    • The brightness temperature is determined by equating the brightness or intensity of an astrophysical source to the intensity of a blackbody and solving for the temperature of the corresponding blackbody.
    • In what regime does the linear relationship between the brightness temperature and the intensity begin to fail?
    • Finally the effective temperature is the temperature of a blackbody that emits the same flux at its surface as the source, i.e.