The temperature of air changes from 0 to 18°C while its velocity changes from zero to a final velocity, and its elevation changes from zero to a final elevation. At which values of final air velocity and final elevation will the internal, kinetic, and potential energy changes be equal? The constant-volume specific heat of air at room temperature is 0.718 kJ/kg·ºC

Internal Energy: is defined as the energy contained within a system (in terms of thermodynamics). It only accounts for any energy changes due to the internal system (thus any outside forces/changes are not accounted for). In S.I. is defined as [tex]U=mC_{V}\Delta T[/tex] where [tex]m[/tex] is the mass (kg), [tex]C_{V}[/tex] is a specific constant-volume (kJ/kg°C) and [tex]\Delta T[/tex] is the Temperature change in °C.

Kinetic Energy: denotes the work done on an object (of given mass [tex]m[/tex]) so that the object at rest, can accelerate to reach a final velocity. In S.I. is defined as [tex]K=\frac{1}{2}mv^2[/tex] where [tex]v[/tex] is the velocity of the object in (m/s).
Potential Energy: denotes the energy occupied by an object (of given mass [tex]m[/tex]) due to its position with respect to another object. In S.I. is defined as [tex]P=mgh[/tex], where [tex]g[/tex] is the gravity constant equal to [tex]9,81m/s^2[/tex] and [tex]h[/tex] is the elevation (meters).

Note: The Internal energy is unaffected by the Kinetic and Potential Energies.

Given Information:

Temperature Change 0°C → 18°C ( thus [tex]\Delta T=18[/tex]°C )
Object velocity we shall call it [tex]v_{o}[/tex] and [tex]v_{f}[/tex], for initial and final, respectively. Here we also know that [tex]v_{o}=0m/s^2[/tex]
Object elevation we shall call it [tex]h_{o}[/tex] and [tex]h_{f}[/tex], for initial and final, respectively. Here we also know that [tex]h_{o}= 0m[/tex]

∴ We are trying to find [tex]v_{f}[/tex] and [tex]h_{f}[/tex] of the air where [tex]U[/tex], [tex]K[/tex] and [tex]P[/tex] are equal.

Lets look at the change in Energy for each.

Step 1: Change in Kinetic Energy=Change in Internal Energy

[tex]\Delta E_{K}=\Delta U\\\frac{1}{2}m{v_{f}}^2- \frac{1}{2}m{v_{o}}^2=mC_{V}\Delta T[/tex]

Here we recall that [tex]v_{o}=0m/s^2[/tex] and mass [tex]m[/tex] is the same everywhere. Thus we have:

[tex]\frac{1}{2}m{v_{f}}^2=mC_{V}\Delta T[/tex]

[tex]\frac{1}{2} {v_{f}}^2=C_{V}\Delta T\\ {v_{f}}^2=2C_{V}\Delta T\\ v_{f}=\sqrt{2C_{V}\Delta T}[/tex] Eqn(1)

Step 2: Change in Potential Energy=Change in Internal Energy

[tex]\Delta E_{P}=\Delta U\\mgh_{f}-mgh_{o}=mC_{V}\Delta T[/tex]

Here we recall that [tex]h_{o}=0m/s^2[/tex] and mass [tex]m[/tex] is the same everywhere. Thus we have:

[tex]mg(h_{f}-h_{o})=mC_{V}\Delta T\\gh_{f}=C_{V}\Delta T\\[/tex]

[tex]h_{f}=\frac{C_{V}\Delta T}{g}[/tex] Eqn(2).

Finally by plugging the known values in Eqns (1) and (2) we obtain:

[tex]v_{f}=\sqrt{2*718*18}=160.77m/s[/tex]

[tex]h_{f}=\frac{718*18}{9.81}=1,317.43m[/tex]

Thus we can conclude that for the air final velocity [tex]v_{f}=160.77m/s[/tex] and final elevation [tex]h_{f}=1,317.43m[/tex] the internal, kinetic, and potential energy changes will be equal.