Why is the internal energy of a gas only dependent on temperature?

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The total internal energy of an ideal gas is expressed as 3/2(NKT) or 3/2(PV), but it primarily depends on temperature rather than volume or pressure. This is because, for ideal gases, the internal energy is determined by the mean kinetic energy of the molecules, which is temperature-dependent. While changes in pressure or volume can affect internal energy through work done on the gas, these effects are negligible in the ideal gas region. Beyond this region, internal energy can also become a function of pressure due to molecular interactions. Thus, for ideal gases, temperature remains the sole determinant of internal energy.
deadscientist
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Hello all,

So the total internal energy of a gas as far as I've been told is 3/2(NKT) but it can also be written as 3/2(PV). Why then is the internal energy only a function of temperature and not volume and pressure as well? Thanks in advance for the help.
 
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You should check the First Law of Thermodynamics.

$$\Delta U = Q\, + \, W$$

Change in pressure or volume, say if the gas is compressed, and hence work is done on the gas, will cause the internal energy to increase.
 
deadscientist said:
Hello all,

So the total internal energy of a gas as far as I've been told is 3/2(NKT) but it can also be written as 3/2(PV). Why then is the internal energy only a function of temperature and not volume and pressure as well? Thanks in advance for the help.

The internal energy is a function of temperature only for an ideal gas. Beyond the ideal gas region, the internal energy is also a function of pressure. The internal energy is determined by the mean kinetic energy of the molecules (including vibrations and rotations) plus the interactions between the molecules (which is related to the pressure). In the ideal gas region, the contribution of the molecular interactions is negligible.
 
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