3.5: First Law of Thermodynamics

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As stated previously, the first law of thermodynamics states that energy is neither created nor destroyed. The total amount of energy must be conserved. In the atmosphere, this means that the amount of heat applied to a mass of air (thermal energy input) must equal the total sum of the warming of the air, plus the amount of work done per unit mass of air.

When heat (\(\Delta q\), J·kg^–1) is added to a mass of air (often referred to as an air parcel, see below), some of the added thermal energy warms the air, which increases its internal energy. When the air parcel warms, one of two things must happen. Recall the ideal gas law from Chapter 1: \(P=\rho \times R_d \times T\). If temperature increases, (1) density must decrease to keep pressure constant or (2) the pressure will increase. Small pressure differences in the atmosphere always equalize first, so as the air warms, the density of the air parcel decreases. The decreased density of the air parcel gives it a lower density than the surrounding air, and it is therefore buoyant and begins to rise. As the parcel rises, it expands in volume in order to maintain equilibrium with the lower pressure outside the air mass, and it pushes into the surrounding atmosphere. Because of this, some of the thermal energy that is added to the air goes into doing the work of expansion and not all of it is used for warming.

\[\text { Heat Added }=\text { Warming }+ \text { Work done by the expanding air } \nonumber \]

\[\Delta q=C_v \times \Delta T+P \times \frac{\Delta V}{m} \nonumber \]

For the atmosphere, a more usable form of the First Law of Thermodynamics is:

\[\text { Heat Transferred }=\text { Enthalpy Change }- \text { Pressure Change per Mass } \nonumber \]

\[\Delta q=C_p \times \Delta T-\frac{\Delta P}{\rho} \nonumber \]

In the atmospheric form of the First Law of Thermodynamics, \(C_p \times \Delta T\) can also be redefined as Enthalpy (\(h\)), a term to quantify the total heat content of an air parcel.

\[\text { Enthalpy Change }=\text { Specific Heat }(@ \text { const } P) \times \text { Temperature Change } \nonumber \]

\[h=C_p \times T \nonumber \]

\[\Delta h=C_p \times \Delta T \nonumber \]

This gives us the first term in the above equation for the first law of thermodynamics.

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