adiabatic

Examples of adiabatic in the following topics:

• Adiabatic Processes

  • In our Atom on "Adiabatic Processes" (category: the First Law of Thermodynamics), we learned that an adiabatic process is any process occurring without gain or loss of heat within a system.
  • We also learned a monatomic ideal gas expands adiabatically.
  • A strong magnetic field is applied to adiabatically align magnetic moments of the particles in the gas.
  • The magnetic field is reduced adiabatically, and thermal energy of the gas causes "ordered" magnetic moments to become random again.
  • This scheme is called adiabatic demagnetization cooling.

• Adiabatic Processes

  • An adiabatic process is any process occurring without gain or loss of heat within a system.
  • In contrast, an adiabatic process is where a system exchanges no heat with its surroundings (Q = 0).
  • (See our atom on "Adiabatic Process. ") In other words, in an isothermal process, the value ΔT = 0 but Q ≠ 0, while in an adiabatic process, ΔT ≠ 0 but Q = 0.

• Detonation Waves

  • The lower curve $a$ is the shock adiabat without the chemical changes and $a'$ is the detonation abiabat which uses the functional form of the enthalpy in the burnt gas.
  • The detonation adiabat below the Jouguet point $E$ cannot be reached if the combustion begins after the gas is compressed.
  • Shock (Hugoniot) Adiabat (in gray), Detonation Adiabat (in black) and Standard (Poisson) Adiabat (in blue).

• Isothermal Processes

  • In contrast, an adiabatic process is where a system exchanges no heat with its surroundings (Q = 0).
  • (See our atom on "Adiabatic Process. ") In other words, in an isothermal process, the value ΔT = 0 but Q ≠ 0, while in an adiabatic process, ΔT ≠ 0 but Q = 0.

• Radiative Shocks

  • Again we still have the relationships between the flux, velocities, slopes and areas on the plane that result from the conservation of momentum and mass, but the shock adiabat is replaced with an isotherm as shown in Figure 12.4.
  • Because the standard adiabats are generally steeper than the isotherms, the gas always leaves the shock subsonically.
  • Isotherm (in black), Shock (Hugoniot) Adiabat (in gray), Standard (Poisson) Adiabats (in blue).

• Carnot Cycles

  • The Carnot cycle comprises two isothermal and two adiabatic processes.
  • Recall that both isothermal and adiabatic processes are, in principle, reversible .
  • PV diagram for a Carnot cycle, employing only reversible isothermal and adiabatic processes.

• Problems

  • You can consider the flow to be adiabatic.

• Non-relativistic Shocks

  • Figure 12.1 depicts the shock or Hugoniot adiabat for a shock with a preshock pressure $p_1$ and specific volume $V_1$.
  • There are two (or no) shock adiabats that connect any two points in the $p-V-$plane.
  • Figure 12.1 shows the curves of constant entropy or standard (Poisson) adiabats on the $p-V-$plane corresponding to the values of the entropy at $(p_1,V_1)$, $s_1$, and at $(p_2,V_2)$, $s_2$.
  • Because all of the adiabats are concave up in the $p-V-$plane, the slope of the secant must be larger than that of the tangent at $(p_1,V_1)$, so the flow enters the shock supersonically.
  • Shock (Hugoniot) Adiabats (in black) and Standard (Poisson) Adiabats (in blue)

• Isotherms

  • In contrast, an adiabatic process occurs when a system exchanges no heat with its surroundings (Q = 0).
  • In other words, in an isothermal process, the value ΔT = 0 but Q ≠ 0, while in an adiabatic process, ΔT ≠ 0 but Q = 0.

• Accretion Disks

  • The solution to Bondi accretion with γ = 7/5 (an adiabatic, diatomic gas).